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ICES ADVICE 2013
AVIS DU CIEM
Books 1- 10
Report of the ICES Advisory
Committee 2013
Book 1
Introduction, Overviews and Special
Requests
International Council for the Exploration of the Sea
Conseil International pour l’Exploration de la Mer
H.C. Andersens Boulevard 44-46
DK-1553 Copenhagen V
Denmark
Telephone (+45) 33 38 67 00
Telefax (+45) 33 93 42 15
www.ices.dk
[email protected]
Report of the ICES Advisory Committee 2013.
Books 1 - 10
December 2013
Recommended format for purposes of citation:
ICES. 2013. Report of the ICES Advisory Committee 2013. ICES Advice, 2013. Books 1-11, 2095 pp.
ICES. 2013. Report of the ICES Advisory Committee 2013. ICES Advice, 2013. Book 1. 348 pp.
For permission to reproduce material from this publication, please apply to the General Secretary.
ISBN 978-87-7482-119-9
TABLE OF CONTENTS
ICES ADVICE 2013
BOOK 1
Section
1
Page
INTRODUCTION, OVERVIEW AND SPECIAL REQUESTS .......................................................................... 1
1.1
About ICES ................................................................................................................................................... 1
1.2
1.3
1.4
1.5
General context of ICES advice .................................................................................................................... 3
Technical basis for the advice ..................................................................................................................... 25
Structure of the Report ................................................................................................................................ 28
Answers to non-Ecoregion specific Special Requests................................................................................. 30
1.5.1
EU DG Mare .............................................................................................................................. 30
1.5.1.1 Request from EU concerning monitoring of bycatch of cetaceans and other protected
species ........................................................................................................................ 30
1.5.1.2 New information regarding the impact of fisheries on other components of the
ecosystem ................................................................................................................... 34
1.5.1.3 Request from EU concerning monitoring of bycatch of seabirds ............................... 39
1.5.2
EU DGENV ............................................................................................................................... 48
1.5.2.1 Request from EU for scientific advice on data collection issues ................................ 48
1.5.2.2 Request from EU for scientific advice on data collection issues – part 2 ................... 59
1.5.3
1.5.4
1.5.5
HELCOM................................................................................................................................... 72
NASCO ................................................................................................................................... 72
NEAFC ................................................................................................................................... 73
1.5.5.1
1.5.5.2
1.5.5.3
1.5.5.4
1.5.5.5
1.5.5.6
1.5.5.7
1.5.6
OSPAR
................................................................................................................................. 195
1.5.6.1
Ecological quality objective for seabird populations in OSPAR Region III (Celtic
Seas) ......................................................................................................................... 195
Data collection and storage to implement the OSPAR seabird recommendations .. 205
OSPAR special request on review of the technical specification and application of
common indicators under D1, D2, D4, and D6 ........................................................ 208
OSPAR special request on maximizing the use of available sources of data for
monitoring of biodiversity ........................................................................................ 222
OSPAR/NEAFC special request on review of results of the Joint OSPAR/NEAFC/
CBD Workshop on EBSAs (same as 1.5.5.5)........................................................... 232
OSPAR/NEAFC special request on Existing and potential new management measures
for EBSAs (same as 1.5.5.6)..................................................................................... 270
OSPAR/NEAFC special request on review and reformulation of four EBSA
Proformas (same as 1.5.5.7) ..................................................................................... 277
OSPAR request on spatial design of a regional monitoring programme for
contaminants in sediments ........................................................................................ 327
1.5.6.2
1.5.6.3
1.5.6.4
1.5.6.5
1.5.6.6
1.5.6.7
1.5.6.8
1.5.7
1.6
1.7
1.8
1.9
Vulnerable deep-water habitats in the NEAFC Regulatory Area ............................... 73
Evaluation of the appropriateness of buffer zones...................................................... 83
Assessment of the list of VME indicator species and elements .................................. 85
Advice on threshold levels for long line fishing ......................................................... 98
OSPAR/NEAFC special request on review of results of the Joint OSPAR/NEAFC/
CBD Workshop on EBSAs (same as 1.5.6.5)............................................................. 99
OSPAR/NEAFC special request on Existing and potential new management measures
for EBSAs (same as 1.5.6.6)..................................................................................... 137
OSPAR/NEAFC special request on review and reformulation of four EBSA
Proformas (same as 1.5.6.7) ..................................................................................... 144
Member States ......................................................................................................................... 334
General trends in the Northeast Atlantic ................................................................................................... 335
Acronyms and terminology ....................................................................................................................... 341
Maps
................................................................................................................................................. 345
List of Reviewers ...................................................................................................................................... 348
ICES Advice 2013, Book 1
i
BOOK 2
Section
2
Page
ICELAND AND EAST GREENLAND ................................................................................................................... 1
2.1
Ecosystem Overview ...................................................................................................................................... 1
2.2
The status of fish stocks and fisheries ............................................................................................................ 1
2.3
Ecosystem Assessments and Advice .............................................................................................................. 5
2.3.1
2.3.2
2.3.3
Assessments and advice regarding protection of biota and habitats............................................... 5
Assessment and advice regarding fisheries .................................................................................... 5
Special Requests ............................................................................................................................ 6
2.3.3.1 Request from Iceland to ICES to evaluate longterm management plan and harvest control
rule for Icelandic haddock ................................................................................................ 6
2.3.3.2 Request from Iceland to ICES to evaluate longterm management plan and harvest control
rule for Icelandic saithe .................................................................................................. 16
2.4
Stock summaries
2.4.1
2.4.2
2.4.3
2.4.4
2.4.5
2.4.6
2.4.7
2.4.8
2.4.9
2.4.10
2.4.11
2.4.12
2.4.13
2.4.14
ii
....................................................................................................................................... 29
Capelin in Subareas V and XIV and Division IIa west of 5°W (Iceland–East Greenland–Jan Mayen
area)
29
Inshore Cod in NAFO Subarea 1 (Greenland Cod)...................................................................... 35
Offshore Cod in ICES Subarea XIV (Greenland cod) ................................................................. 41
Cod in Division Va (Icelandic cod).............................................................................................. 43
Greenland halibut in Subareas V, VI, XII and XIV ..................................................................... 51
Haddock in Division Va (Icelandic haddock) .............................................................................. 64
Herring in Division Va (Icelandic summer-spawning herring) .................................................... 71
Introduction to the redfish complex in Subareas V, VI, XII, XIV ............................................... 77
Beaked Redfish (Sebastes mentella) in Division Va and Subarea XIV (Icelandic Slope stock)...91
Beaked Redfish (Sebastes mentella) in Subareas V, XII, XIV and NAFO Subareas 1+2
(Shallow Pelagic stock <500 m) .................................................................................................. 99
Beaked Redfish (Sebastes mentella) in Subareas V, XII, XIV and NAFO
Subareas 1+2 (Deep Pelagic stock >500 m)............................................................................... 108
Beaked Redfish (Sebastes mentella) in subarea XIVb (Demersal) ............................................ 117
Golden Redfish (Sebastes marinus) in Subareas V, VI, XII and XIV ....................................... 118
Saithe in Division Va (Icelandic saithe) ..................................................................................... 120
ICES Advice 2013, Book 1
BOOK 3
Section
3
Page
THE BARENTS SEA AND THE NORWEGIAN SEA ......................................................................................... 1
3.1
Ecosystem overview ....................................................................................................................................... 1
3.2
The status of fish stocks and fisheries ............................................................................................................ 1
3.3
Ecosystem Assessments and Advice .............................................................................................................. 5
3.4
3.3.1
Assessments and advice regarding protection of biota and habitats............................................... 5
3.3.2
Assessment and advice regarding fisheries .................................................................................... 5
3.3.3
Special Requests ............................................................................................................................ 6
3.3.3.1 Status and harvest potential of the harp seal stocks in the Greenland Sea and the White
Sea/Barents Sea, and of the hooded seal stock in the Greenland Sea ..................................... 6
Stock summaries ....................................................................................................................................... 21
3.4.1
3.4.2
3.4.3
3.4.4
3.4.5
3.4.6
3.4.7
3.4.8
3.4.9
Capelin in Subareas I and II, excluding Division IIa west of 5°W (Barents Sea capelin) ........... 21
Cod in Subareas I and II (Northeast Arctic cod) .......................................................................... 32
Cod in Subareas I and II (Norwegian coastal waters cod) ........................................................... 43
Haddock in Subareas I and II (Northeast Arctic) ......................................................................... 50
Greenland halibut in Subareas I and II ........................................................................................ 60
Beaked redfish (Sebastes mentella) in Subareas I and II ............................................................. 66
Golden redfish (Sebastes marinus) in Subareas I and II .............................................................. 74
Saithe in Subareas I and II (Northeast Arctic) ............................................................................. 81
Northern shrimp (Pandalus borealis) in Subareas I and II (Barents Sea) .................................... 89
ICES Advice 2013, Book 1
iii
BOOK 4
Section
4
Page
THE FAROE PLATEAU ECOSYSTEM ............................................................................................................... 1
4.1
Ecosystem Overview ...................................................................................................................................... 1
4.2
The status of fish stocks and fisheries ............................................................................................................ 1
4.3
Ecosystem Assessments and Advice ............................................................................................................. 6
4.3.1
4.3.2
4.4
iv
Assessments and advice regarding protection of biota and habitats............................................... 6
Assessment and advice regarding fisheries .................................................................................... 6
Stock summaries
......................................................................................................................................... 7
4.4.1
Cod in Subdivision Vb1 (Faroe Plateau) ........................................................................................ 7
4.4.2
Cod in Subdivision Vb2 (Faroe Bank).......................................................................................... 15
4.4.3
Haddock in Division Vb .............................................................................................................. 20
4.4.4
Saithe in Division Vb ................................................................................................................... 29
ICES Advice 2013, Book 1
BOOK 5
Section
5
Page
CELTIC SEA AND WEST OF SCOTLAND ......................................................................................................... 1
5.1
5.2
5.3
5.4
Ecosystem Overview ...................................................................................................................................... 1
The status of fish stocks and fisheries ............................................................................................................ 1
Ecosystem Assessments and Advice ........................................................................................................... 13
5.3.1
Assessments and advice regarding protection of biota and habitats............................................. 13
5.3.2
Assessment and advice regarding fisheries .................................................................................. 16
5.3.3
Special requests ............................................................................................................................ 17
5.3.3.1 Request from the European Commission on distribution of the stock of megrims in Subarea IV
and Division VIa .......................................................................................................................... 17
5.3.3.2 Request from NEAFC to evaluate the proposals for the harvest control components of the
management plan for Rockall haddock fisheries.......................................................................... 20
5.3.3.3 Request from NEAFC on the closure area and additional measures for the protection of juvenile
haddock on Rockall Bank ............................................................................................................ 28
Fish stock advice ....................................................................................................................................... 34
5.4.1
Anglerfish (Lophius piscatorius and L. budegassa) in Divisions IIIa, and Subareas IV and VI .. 34
5.4.2
Anglerfish (Lophius piscatorius and L. budegassa) in Divisions VIIb-k and VIIIa,b,d .............. 51
5.4.3
Cod in Division VIa (West of Scotland) ...................................................................................... 59
5.4.4
Cod in Division VIb (Rockall) ..................................................................................................... 72
5.4.5
Cod in Division VIIa (Irish Sea) .................................................................................................. 74
5.4.6
Cod in Divisions VIIe-k (Celtic Sea cod) .................................................................................... 76
5.4.7
Grey gurnard in Subarea VI and Divisions VIIa-c and e-k (Celtic Sea and West of Scotland) ... 85
5.4.8
Haddock in Division VIa (West of Scotland)............................................................................... 87
5.4.9
Haddock in Division VIb (Rockall) ............................................................................................. 98
5.4.10
Haddock in Division VIIa (Irish Sea)......................................................................................... 108
5.4.11
Haddock in Divisions VIIb-k ..................................................................................................... 117
5.4.12
Herring in Division VIa North ................................................................................................... 124
5.4.13
Herring in Divisions VIa (South) and VIIb,c ............................................................................. 135
5.4.14
Herring in Division VIIa North of 52° 30´ N (Irish Sea) ........................................................... 143
5.4.15
Herring in Divisions VIIa South of 52° 30´ N and VIIg,h,j,k (Celtic Sea and South of
Ireland) ......................................................................................................................... 151
5.4.16
Lesser-spotted dogfish (Scyliorhinus canicula) in Subdivisions VI, VIIa-c, e-j ........................ 161
5.4.17
Megrim (Lepidorhombus spp.) in Divisions IV (North Sea) and Division Via (West of
Scotland) ...................................................................................................................... 162
5.4.18
Megrim (Lepidorhombus spp) inDivision VIb (Rockall) ........................................................... 172
5.4.19
Megrim (Lepidorhombus whiffiagonis) in Divisions VIIb-k and VIIIa,b,d ............................... 178
5.4.20
Nephrops in Division VIa .......................................................................................................... 181
5.4.20.1 Nephrops in North Minch (FU 11) ............................................................................. 189
5.4.20.2 Nephrops in the South Minch (FU 12) ....................................................................... 198
5.4.20.3 Nephrops in the Firth of Clyde + Sound of Jura (FU 13) ........................................... 207
5.4.21
Nephrops in Subarea VII ............................................................................................................ 220
5.4.21.1 Nephrops in Irish Sea East (FU14) ............................................................................. 229
5.4.21.2 Nephrops in Irish Sea West (FU 15) .......................................................................... 236
5.4.21.3 Nephrops on Porcupine Bank (FU 16) ....................................................................... 246
5.4.21.4 Nephrops on Aran Grounds (FU 17) ........................................................................... 255
5.4.21.5 Nephrops off the south-eastern and south-western coasts of Ireland (FU 19) ............. 264
5.4.21.6 Nephrops in the FU 20 (Labadie, Baltimore and Galley), FU 21 (Jones and
Cockburn)................................................................................................................................... 273
5.4.21.7 Nephrops in the Smalls (FU 22) .................................................................................. 277
5.4.22
Norway pout in Division VIa (West of Scotland) ...................................................................... 284
5.4.23
Plaice in Division VIIa (Irish Sea) ............................................................................................. 286
5.4.24
Plaice in Division VIIb,c (West of Ireland)................................................................................ 294
5.4.25
Plaice in Division VIIe (Western Channel) ................................................................................ 296
5.4.26
Plaice in Divisions VIIf,g (Celtic Sea) ....................................................................................... 305
5.4.27
Plaice in Divisions VIIh-k (Southwest of Ireland) ..................................................................... 313
5.4.28
Pollack in SubareasVI and VII (Celtic Sea and West of Scotland) ........................................... 319
5.4.29
Rays and Skates in the Celtic Seas ecoregion ............................................................................ 321
5.4.29.1 Rays and Skates in the Celtic Seas ecoregion ............................................................. 323
ICES Advice 2013, Book 1
v
5.4.30
5.4.31
5.4.32
5.4.33
5.4.34
5.4.35
5.4.36
5.4.37
5.4.38
5.4.39
5.4.40
5.4.41
5.4.42
5.4.43
5.4.44
vi
5.4.29.2 Blonde ray (Raja brachyura) in Subarea VI ............................................................... 325
5.4.29.3 Blonde ray (Raja brachyura) in Divisions VIIa,f,g..................................................... 325
5.4.29.4 Blonde ray (Raja brachyura) in Division VIIe ........................................................... 326
5.4.29.5 Thornback Ray (Raja clavata) in Sybarea VI ............................................................. 327
5.4.29.6 Thornback Ray (Raja clavata) in Divisions VIIa,f,g .................................................. 328
5.4.29.7 Thornback ray (Rajaclavata) in Division VIIe............................................................ 329
5.4.29.8 Small-eyed ray (Raja microocellata) in Divisions VIIfg ............................................ 330
5.4.29.9 Small-eye ray (Raja microcellata) in Division VIIe ................................................... 331
5.4.29.10 Spotted ray (Raja montagui) in Subarea VI ............................................................... 332
5.4.29.11 Spotted ray (Raja montagui) in Divisions VIIa,f,g .................................................... 333
5.4.29.12 Raja undulata in Division VIIj ................................................................................... 334
5.4.29.13 Sandy ray (Leucoraja circularis) in the Celtic Seas.................................................. 335
5.4.29.14 Shagreen ray (Leucoraja fullonica) in the Celtic Seas ............................................... 336
5.4.29.15 Cuckoo ray, Leucoraja naevus in Subarea VI and Division VIIa-c, e-j .................... 337
5.4.29.16 Common skate Dipturus batis complex (flapper skate Dipturus cf. flossada and blue
skate Dipturus cf. intermedia) in Subarea VI, and Divisions VIIa-c, e-j ................... 338
5.4.29.17 Other ray and skate species in Subarea VI, and Divisions VIIa-c, e-j ....................... 338
Saithe in Subarea VI (West of Scotland and Rockall) ............................................................... 339
Sandeel in Division VIa (West of Scotland) .............................................................................. 340
European seabass in Divisions IVbc, Via and VIId-h (Irish Sea, English Channel and southern
North Sea) .................................................................................................................................. 341
European seabass in Divisions Via, VIIb and VIIj (West of Scotland and Ireland) ................... 349
Sole in Division VIIa (Irish Sea) ................................................................................................ 355
Sole in Division VIIb,c (West of Ireland) .................................................................................. 362
Sole in Division VIIe (Western Channel) .................................................................................. 364
Sole in Divisions VIIf,g (Celtic Sea) ......................................................................................... 372
Sole in Division VIIh-k (Southwest of Ireland) ......................................................................... 380
Sprat in Subarea VI and Divisions VIIa-c and f-k (Celtic Sea and West of Scotland)............... 386
Sprat in Divisions VIId,e (Channel) ........................................................................................... 388
Whiting in Division VIa (West of Scotland) .............................................................................. 395
Whiting in Division VIb (Rockall)............................................................................................. 403
Whiting in Division VIIa (Irish Sea) .......................................................................................... 405
Whiting in Divisions VIIe-k (Celtic Sea whiting) ...................................................................... 407
ICES Advice 2013, Book 1
BOOK 6
Section
6
Page
NORTH SEA
......................................................................................................................................... 1
6.1
Ecosystem Overview ...................................................................................................................................... 1
6.2
The status of fish stocks and fisheries ............................................................................................................ 1
6.3
Ecosystem Assessments and Advice ............................................................................................................ 15
14
6.3.1
6.3.2
6.3.3
6.3.4
6.3.5
6.4
Multispecies considerations for the North Sea stocks (WGSAM) .............................................. 15
Mixed-fisheries advice for Subarea IV (North Sea) and Divisions IIIa North (Skagerrak) and
VIId (Eastern Channel) (WGMIXFISH) ..................................................................................... 24
Assessments and advice regarding protection of biota and habitats............................................. 34
Assessment and advice regarding fisheries .................................................................................. 34
Special requests ............................................................................................................................ 35
6.3.5.1 EU request on changing the TAC year for Norway pout in the North Sea .................... 35
6.3.5.2 Joint EU-Norway request to evaluate the long-term management plan for whiting in the
North Sea ....................................................................................................................... 42
6.3.5.3 EU request on inter-annual quota flexibility plaice in the North Sea ............................ 49
6.3.5.4 EU request on inter-annual quota flexibility saithe in the North Sea............................. 52
6.3.5.5 Joint EU-Norway request on TAC setting options for cod in the North Sea and
Skagerrak ....................................................................................................................... 55
Fish stock advice
6.4.1
6.4.2
6.4.3
6.4.4
6.4.5
6.4.6
6.4.7
6.4.8
6.4.9
6.4.10
6.4.11
6.4.12
6.4.13
6.4.14
6.4.15
6.4.16a
6.4.16b
6.4.17
6.4.18
6.4.19
6.4.20
6.4.21
6.4.22
Brill in Subarea IV and Divisions IIIa and VIId,e ....................................................................... 63
Cod in Division IIIa East (Kattegat) ............................................................................................ 69
Cod in Subarea IV (North Sea) and Divisions VIId (Eastern Channel) and IIIa West (Skagerrak)
71
Dab in Subarea IV and Division IIIa ............................................................................................ 91
Flounder in Subarea IV and Division IIIa .................................................................................... 98
Grey gurnard in Subarea IV (North Sea) and Divisions VIId (Eastern Channel) and IIIa
(Skagerrak - Kattegat)…………………………………………………………………104
Haddock in Subarea IV (North Sea) and Division IIIa West (Skagerrak).................................. 105
Herring in Division IIIa and Subdivisions 22–24 (Western Baltic spring spawners)................. 119
Herring in Subarea IV and Divisions IIIa and VIId (North Sea autumn spawners) ................... 130
Horse mackerel (Trachurus trachurus) in Divisions IIIa, IVb,c and VIId (North Sea stock) .... 148
Lemon sole in Subarea IV, and Divisions IIIa and VIId ………………………………………155
Lesser-spotted dogfish (Scyliorhinus canicula) in IIIa, IV and VIId ........................................ 160
Striped red mullet in Subarea IV (North Sea) and Divisions VIId (Eastern English Channel) and
IIIa (Skagerrak–Kattegat) .......................................................................................................... 161
Nephrops in Division IIIa........................................................................................................... 169
Nephrops in Division IV (North Sea) ....................................................................................... 176
6.4.15.1 Nephrops in Botney Gut – Silver Pit (FU 5) .............................................................. 184
6.4.15.2 Nephrops in Farn Deeps (FU 6) .................................................................................. 185
6.4.15.3 Nephrops in Fladen Ground (FU 7) ........................................................................... 192
6.4.15.4 Nephrops in Firth of Forth (FU 8) ............................................................................... 199
6.4.15.5 Nephrops in Moray Firth (FU 9) ................................................................................. 207
6.4.15.6 Nephrops in Noup (FU 10).......................................................................................... 214
6.4.15.7 Nephrops in Norwegian Deeps (FU 32) ...................................................................... 215
6.4.15.8 Nephrops off Horn’s Reef (FU 33) ............................................................................ 216
6.4.15.9 Nephrops in Devil’s Hole (FU 34) ............................................................................... 217
Norway pout in Subarea IV (North Sea) and Division IIIa (Skagerrak – Kattegat) June advice 217
Norway pout in Subarea IV (North Sea) and Division IIIa (Skagerrak – Kattegat) October
advice.......................................................................................................................................... 228
Plaice in Division IIIa West (Skagerrak) ................................................................................... 237
Plaice in Subarea IV (North Sea) ............................................................................................... 248
Plaice in Division VIId (Eastern Channel) ................................................................................. 261
Pollack in Subarea IV and Division IIIa ................................................................................... 267
Saithe in Subarea IV (North Sea) Division IIIa (Skagerrak) and Subarea VI (West of Scotland
and Rockall) ................................................................................................................. 268
Sandeel in Division IIIa and Subarea IV .......................................................................................... 280
6.4.22.1 Sandeel in the Doggerbank area (SA 1)....................................................................... 287
ICES Advice 2013, Book 1
vii
6.4.22.2
6.4.22.3
6.4.22.4
6.4.22.5
6.4.22.6
6.4.22.7
6.4.23
6.4.24
6.4.25
6.4.26
6.4.27
6.4.28
6.4.29
6.4.30
6.4.31
6.4.32
6.4.33
6.4.34
6.4.35
viii
Sandeel in the South Eastern North Sea (SA 2) ........................................................... 292
Sandeel in the Central Eastern North Sea (SA 3) ........................................................ 297
Sandeel in the Central Western North Sea (SA 4) ....................................................... 303
Sandeel in the Viking and Bergen Bank area (SA 5) ................................................... 307
Sandeel in Division IIIa East (Kattegat, SA6) ............................................................. 309
Sandeel in the Shetland area (SA 7) ............................................................................ 311
Northern shrimp (Pandalus borealis) in Divisions IIIa West and IVa East (Skagerrak and
Norwegian Deeps)........................................................................................................ 313
Northern shrimp (Pandalus borealis) in Division IVa (Fladen Ground) ................................... 324
Rays and skates in Divisions and Subareas IIIa, IV, and VIId, e (Kattegat, Skagerrak, North Sea,
and English Channel) ................................................................................................................. 325
6.4.25.1 Blonde ray (Raja brachyuran) in Divisions IVc and VIId, e (Southern North Sea and
English Channel) ......................................................................................................... 327
6.4.25.2 Thornback ray (Raja clavata) in Subarea IV and in Divisions IIIa and VIId, e (North
Sea, Skagerrak, Kattegat, and English Channel) ......................................................... 328
6.4.25.3 Small-eyed ray (Raja microocellata) in Divisions VIId, e (English Channel) ............ 329
6.4.25.4 Spotted ray (Raja montagui) in Subarea IV and in Divisions IIIa and VIId (North Sea,
Skagerrak, Kattegat, and eastern English Channel) ..................................................... 330
6.4.25.5 Undulate ray (Raja undulata) in Divisions VIId, e (English Channel) ........................ 331
6.4.25.6 Cuckoo ray (Leucoraja naevus) in Subarea IV and in Divisions IIIa and VIId (North
Sea, Skagerrak, Kattegat, and eastern English Channel) ............................................. 332
6.4.25.7 Common skate (Dipturus batis) complex (Dipturus cf. flossada and Dipturus cf.
intermedia) in Subarea IV and in Divisions IIIa and VIId (North Sea, Skagerrak,
Kattegat, and eastern English Channel) ....................................................................... 333
6.4.25.8 Starry ray (Amblyraja radiata) in Subarea IV and in Divisions IIIa and VIId (North Sea
Skagerrak, Kattegat, and eastern English Channel) ...................................................... 334
6.4.25.9 Other ray and skate species in Subarea IV and in Divisions IIIa and VIId (North Sea,
Skagerrak, Kattegat, and eastern English Channel) .................................................... 335
Sole in Division IIIa and Subdivisions 22–24 (Skagerrak, Kattegat, and the Belts) .................. 336
Sole in Subarea IV (North Sea) .................................................................................................. 346
Sole in Division VIId (Eastern Channel) ................................................................................... 361
Sprat in Division IIIa (Skagerrak – Kattegat)............................................................................. 371
Sprat in the Subarea IV (North Sea)........................................................................................... 377
Turbot in Division IIIa ............................................................................................................... 387
Turbot in Subarea IV (North Sea) .............................................................................................. 393
Whiting in Division IIIa (Skagerrak – Kattegat) ........................................................................ 395
Whiting in Subarea IV (North Sea) and Division VIId (Eastern Channel) ................................ 401
Witch in Subarea IV, and Divisions IIIa and VIId ..................................................................... 416
ICES Advice 2013, Book 1
BOOK 7
Section
7
Page
BAY OF BISCAY AND ATLANTIC IBERIAN WATERS ................................................................................. 1
7.1
Ecosystem Overview ...................................................................................................................................... 1
7.2
The status of fish stocks and fisheries ............................................................................................................ 1
7.3
Ecosystem Assessments and Advice .............................................................................................................. 7
7.3.1
Multispecies advice ........................................................................................................................ 7
7.3.2
Mixed fisheries advice for the Bay of Biscay and Atlantic Iberian Waters ................................... 7
7.3.3
Assessment and advice regarding protection of biota and habitats ............................................... 7
7.3.4
Assessments and advice regarding fisheries .................................................................................. 7
7.3.5
Special requests ............................................................................................................................. 8
7.3.5.1 EU request to evaluate the management plan for Iberian sardine ..................................... 8
7.3.5.2 EU request for the evaluation of the harvest control rule for sole
in the Bay of Biscay ................................................................................................................... 16
7.4
Fish stock advice .......................................................................................................................................... 21
7.4.1
Anchovy in Subarea VIII (Bay of Biscay) .................................................................................. 21
7.4.2
Anchovy in Division IXa (West of Galicia, Portuguese coast and Golf of Cadiz) ..................... 30
7.4.3
Black-bellied anglerfish (Lophius budegassa) in Divisions VIIIc and IXa (Atlantic Iberian waters)
37
7.4.4
White anglerfish (Lophius piscatorius) in Divisions VIIIc and IXa (Atlantic Iberian waters).... 44
7.4.5
Blue Jack mackerel (Trachurus picturatus) in Subdivision Xa2 (Azores) .................................. 52
7.4.6
Grey gurnard in Subarea VIII and Division IXa (Bay of Biscay and Atlantic Iberian waters) ... 54
7.4.7
Hake in Division VIIIc and IXa (Southern stock) ....................................................................... 55
7.4.8
Horse mackerel (Trachurus trachurus) in Division IXa (Southern stock) .................................. 67
7.4.9
Four spot megrim (Lepidorhombus boscii) in Divisions VIIIc and IXa (Bay of Biscay and Atlantic
Iberian waters) ............................................................................................................................. 73
7.4.10
Lesser-spotted dogfish (Scyliorhinus canicula) in VIII and IX ................................................... 81
7.4.11
Lesser-spotted dogfish (Scyliorhinus canicula) in VIIIc and IXa ............................................... 82
7.4.12
Megrim (Lepidorhombus whiffiagonis) in Divisions VIIIc and IXa (Bay of Biscay and Atlantic
Iberian waters) ............................................................................................................................. 83
7.4.13
Nephrops in Divisions VIIIa,b (Bay of Biscay, FU 23–24) ........................................................ 90
7.4.14
Nephrops in Division VIIIc (North Galicia and Cantabrian Sea, FU 25 and 31) ........................ 92
7.4.14.1 Nephrops in North Galicia (FU 25) .............................................................................. 95
7.4.14.2 Nephrops in the Cantabrian Sea (FU 31) ....................................................................... 97
7.4.15
Nephrops in Divisions IXa (West of Galicia, Portuguese coast and Golf of Cadiz). .................. 99
7.4.15.1 Nephrops in West Galicia and North Portugal (FU 26–27) ........................................ 103
7.4.15.2 Nephrops in South-West and South Portugal (FU 28–29) .......................................... 104
7.4.15.3 Nephrops in Gulf of Cadiz (FU 30) ............................................................................ 106
7.4.16
Plaice in Subarea VIII and Division IXa (Bay of Biscay and Atlantic Iberian waters) ............. 107
7.4.17
Pollack in Subarea VIII and Division IXa (Bay of Biscay and Atlantic Iberian waters) .......... 109
7.4.18
Rays and skates in Subareas VIII and IX (Bay of Biscay and Atlantic Iberian waters) ............ 111
7.4.18.1 Thornback ray (Raja clavata) in Subarea VIII (Bay of Biscay and Cantabrian Sea) .... 113
7.4.18.2 Cuckoo ray (Leucoraja naevus) in Subarea VIII (Bay of Biscay and Cantabrian Sea) .. 114
7.4.18.3 Spotted ray (Raja montagui) in Subarea VIII (Bay of Biscay and Cantabrian Sea) ....... 115
7.4.18.4 Spotted ray (Raja montagui) in Division IXa (west of Galicia, Portugal, and Gulf of
Cadiz)................................................................................................................................. 116
7.4.18.5 Cuckoo ray (Leucoraja naevus) in Division IXa (west of Galicia, Portugal, and Gulf of
Cadiz)................................................................................................................................. 117
7.4.18.6 Thornback ray (Raja clavata) in Division IXa (west of Galicia, Portugal, and Gulf of
Cadiz)................................................................................................................................. 118
7.4.18.7 Blonde ray (Raja brachyuran) in Division IXa (west of Galicia, Portugal, and Gulf of
Cadiz)................................................................................................................................ 119
7.4.18.8 Common skate (Dipturus batis) complex (flapper skate (Dipturus cf. flossada) and blue
skate (Dipturus cf. intermedia)) in Subarea VIII and Division IXa (Bay of Biscay and
Atlantic Iberian waters) .............................................................................................. 120
7.4.18.9 Other skates and rays in Subarea VIII and Division IXa (Bay of Biscay and
Atlantic Iberian waters) ................................................................................................ 121
7.4.19
7.4.20
7.4.21
Sardine in Division VIIIc and IXa (Bay of Biscay and Atlantic Iberian waters) ...................... 122
Sardine in Divisions VIIIa,b,d and Subarea VII ........................................................................ 131
Sole in Divisions VIIIa,b (Bay of Biscay) ................................................................................. 137
ICES Advice 2013, Book 1
ix
7.4.22
7.4.23
7.4.24
7.4.25
7.4.26
x
Sole in Divisions VIIIc and IXa (Atlantic Iberian waters) ........................................................ 147
Whiting in Subarea VIII and Division IXa (Bay of Biscay and Atlantic Iberian waters).......... 149
No advice................................................................................................................................... 151
European sea bass in Divisions VIIIa,b (Bay of Biscay) ........................................................... 151
European sea bass in Divisions VIIIc and IXa (Atlantic Iberian waters) .................................. 156
ICES Advice 2013, Book 1
BOOK 8
Section
8
Page
THE BALTIC SEA
8.1
8.2
8.3
......................................................................................................................................... 3
Ecosystem Overview ...................................................................................................................................... 3
The status of fish stocks and fisheries ............................................................................................................ 3
Ecosystem Assessments and Advice .............................................................................................................. 8
8.3.1
Assessments and advice regarding protection of biota and habitats............................................... 8
8.3.2
Assessments and advice regarding fisheries................................................................................... 8
8.3.3
Multispecies considerations for the central Baltic stocks: cod in Subdivisions 25–32, herring in
Subdivisions 25–29 and 32, and sprat in Subdivisions 22–32 ....................................................... 9
8.3.4
Special Requests .......................................................................................................................... 15
8.3.4.1 Review of HELCOM draft Red List assessment of cod (Gadus morhua) ..................... 15
8.4
Fish stock advice ....................................................................................................................................... 19
8.4.1
8.4.2
8.4.3
8.4.4
8.4.5
8.4.6
8.4.7
8.4.8
8.4.9
8.4.10
8.4.11
8.4.12
8.4.13
8.4.14
8.4.15
8.4.16
8.4.17
Brill in Subdivisions 22–32 (Baltic Sea) ...................................................................................... 19
Cod in Subdivisions 22–24 (Western Baltic Sea) ........................................................................ 25
Cod in Subdivisions 25–32(Eastern Baltic Sea) ........................................................................... 37
Dab in Subdivisions 22–32 (Baltic Sea)....................................................................................... 48
Flounder in Subdivisions 22–32 (Baltic Sea) ............................................................................... 55
Herring in Division IIIa and Subdivisions 22–24 (Western Baltic spring spawners) .................. 68
Herring in Subdivisions 25–29 and 32 (excluding Gulf of Riga herring) .................................... 69
Herring in Subdivision 28.1 (Gulf of Riga) ................................................................................. 79
Herring in Subdivision 30 (Bothnian Sea) ................................................................................... 88
Herring in Subdivision 31 (Bothnian Bay)................................................................................... 95
Plaice in Subdivisions 21–23 (Kattegat, Belts and Sound) ........................................................ 103
Plaice in Subdivisions 24–32 (Baltic Sea) ................................................................................. 110
Salmon in Subdivisions 22–31 (Main Basin and Gulf of Bothnia) ............................................ 118
Salmon in Subdivision 32 (Gulf of Finland) .............................................................................. 142
Sprat in Subdivisions 22–32 (Baltic Sea) ................................................................................... 154
Sea Trout in Subdivisions 22– 32 (Baltic Sea)........................................................................... 166
Turbot in Subdivisions 22–32 (Baltic Sea) ................................................................................ 168
ICES Advice 2013, Book 1
xi
BOOK 9
Section
9
WIDELY DISTRIBUTED AND MIGRATORY STOCKS .................................................................................. 1
9.1
Ecosystem overview ....................................................................................................................................... 1
9.2
The status of fish stocks and fisheries ............................................................................................................ 1
9.3
Assessments and advice ................................................................................................................................. 5
9.3.1
Assessments and advice regarding protection of biota and habitats............................................... 5
9.3.2
Assessments and advice regarding fisheries................................................................................... 5
9.3.3
Special requests .............................................................................................................................. 6
9.3.3.1 NEAFC request to ICES to evaluate the Harvest Control Rule element of the long-term
management plan for blue whiting .................................................................................. 6
9.3.3.2 NEAFC request to ICES to evaluate possible modifications of the long-term management
arrangement for the Norwegian Spring-Spawning herring stock ................................... 20
9.3.3.3 EU request on Technical Evaluation of Eel Management Plan Progress ....................... 34
9.3.3.4 EC request to ICES to evaluate possible modifications of the long-term management
arrangement for the Western horse mackerel stock ....................................................... 50
9.3.3.5 NEAFC request on effects on assessments of historical unaccounted landings for
mackerel and the utility of new and existing surveys..................................................... 57
9.3.3.6 EC request to ICES to evaluate the proposed long-term management plan for boarfish
and possible in-year revision of the TAC for 2013 ........................................................ 59
9.3.3.7 NEAFC request to ICES to evaluate the extra harvest control rule options for the longterm management plan for blue whiting......................................................................... 61
9.4
xii
Page
Fish stock advice ....................................................................................................................................... 69
9.4.1
Alfonsinos/Golden eye perch (Beryx spp.) in the Northeast Atlantic ......................................... 69
9.4.2
Angel shark (Squatina squatina) in the North East Atlantic ........................................................ 70
9.4.3
Basking shark (Cetorhinus maximus) in the Northeast Atlantic .................................................. 71
9.4.4
Black scabbard fish (Aphanopus carbo) in the Northeast Atlantic .............................................. 72
9.4.5
Blue whiting in Subareas I-IX, XII and XIV (Combined stock) .................................................. 73
9.4.6
Boarfish in the Northeast Atlantic ................................................................................................ 87
9.4.7
European Eel ................................................................................................................................ 98
9.4.8
Greater forkbeard (Phycis blennoides) in the Northeast Atlantic ............................................... 105
9.4.9
Greater Silver Smelt (Argentina silus) in the Northeast Atlantic ............................................... 106
9.4.10
Hake in Division IIIa, Subareas IV, VI and VII and Divisions VIIIa,b,d (Northern stock) ....... 107
9.4.11
Herring
in
Subareas
I,
II,
V
and
Divisions
IVa
and
XIVa
(Norwegian spring-spawning herring) …………………………………………………….... 118
9.4.12
Horse mackerel (Trachurus trachurus) in Divisions IIa, IVa, Vb, VIa, VIIa-c, e-k, and Subarea ...
VIII (Western stock) .................................................................................................................. 130
9.4.13
Kitefin shark (Dalatias licha) in the Northeast Atlantic ............................................................ 149
9.4.14
Leafscale gulper shark (Centrophorus squamosus) in the Northeast Atlantic ........................... 150
9.4.15
Ling (Molva molva) in the Northeast Atlantic ........................................................................... 151
9.4.16
Blue ling (Molva dypterygia) in the Northeast Atlantic ............................................................. 152
9.4.17
Mackerel in the Northeast Atlantic (combined Southern, Western and North Sea spawning
components) ............................................................................................................................... 153
9.4.18
Orange roughy (Hoplostethus atlanticus) in the Northeast Atlantic .......................................... 171
9.4.19
Porbeagle (Lamna nasus) in the Northeast Atlantic ................................................................... 172
9.4.20
Portuguese dogfish (Centroscymnus coelolepis) and leafscale gulper shark
(Centrophorus squamosus) in the Northeast Atlantic ................................................................ 173
9.4.21
Rays and skates (mainly thornback ray) in the Azores and Mid-Atlantic Ridge
(ICES Divisions X, XII, XIV).................................................................................................... 174
9.4.22
Red (=blackspot) seabream (Pagellus bogaraveo) in the Northeast Atlandic............................ 175
9.4.23
Roundnose grenadier (Coryphaenoides rupenstris) in the Northeast Atlantic ........................... 176
9.4.24
Smooth-hounds (Mustelus spp.) in the Northeast Atlantic ......................................................... 178
9.4.25
Red gurnard in the Northeast Atlantic ........................................................................................ 179
9.4.26
Spurdog (Squalus acanthias) in the Northeast Atlantic ............................................................. 180
9.4.27
Striped red mullet in the Northeast Atlantic ............................................................................... 181
9.4.28
Tope,(Galeorhinus galeus) in the Northeast Atlantic ................................................................ 182
9.4.29
Tusk (Brosme brosme) in the Northeast Atlantic ....................................................................... 183
ICES Advice 2013, Book 1
BOOK 10
Section
Page
10 NORTH ATLANTIC SALMON STOCKS ............................................................................................................ 1
10.1
Introduction
10.1.1
10.1.2
10.1.3
10.1.4
10.1.5
Main Tasks ..................................................................................................................................... 1
Management framework for salmon in the North Atlantic ............................................................ 2
Management objectives .................................................................................................................. 3
Reference points and application of precaution ............................................................................. 3
Catch of North Atlantic Salmon ..................................................................................................... 4
10.1.5.1
10.1.5.2
10.1.5.3
10.1.5.4
10.1.6
......................................................................................................................................... 1
Nominal catch of salmon ................................................................................................. 4
Unreported catches .......................................................................................................... 5
Catch-and-release ............................................................................................................ 5
Farming and sea ranching of Atlantic salmon ................................................................. 6
NASCO has asked ICES to report on significant, new or emerging threats to, or opportunities for,
salmon conservation and management ........................................................................................... 6
10.1.6.1
10.1.6.2
10.1.6.3
10.1.6.4
10.1.6.5
Dam Impact Analysis Model for Atlantic Salmon in the Penobscot River, Maine ......... 6
Marine influences on North American Atlantic salmon populations ............................... 6
West Greenland foraging ecology and implications for survival..................................... 7
Tracking and acoustic tagging studies in Greenland and Canada .................................... 7
The impact of artificial night light on Atlantic salmon fry dispersal and the
onset of smolt migration ................................................................................................ 10
10.1.6.6 Stock Identification of Salmon caught in the Faroes Fishery ........................................ 10
10.1.6.7 Update on EU project ECOKNOWS ............................................................................. 10
10.1.6.8 Diseases and parasites.................................................................................................... 12
10.1.6.9 Changing biological characteristics of salmon .............................................................. 13
10.1.6.10 New initiatives in relation to management of mixed-stock coastal fisheries in
northern Norway ............................................................................................................ 14
10.1.7
10.1.8
10.1.9
10.1.10
10.1.11
10.1.12
10.1.13
NASCO has asked ICES to provide a review of examples of successes and failures in wild
salmon restoration and rehabilitation and develop a classification of activities which could be
recommended under various conditions or threats to the persistence of populations................... 14
NASCO has asked ICES to advise on the potential threats to Atlantic salmon from exotic
salmonids including rainbow trout and brown trout where appropriate ....................................... 15
Reports from ICES Expert Group Reports relevant to North Atlantic salmon ............................ 19
NASCO has asked ICES to provide a compilation of tag releases by country in 2012 ............... 20
NASCO has asked ICES to further develop a risk-based framework for the provision of catch
advice for the Faroese salmon fishery reporting on the implications of selecting different
numbers of management units...................................................................................................... 20
NASCO has asked ICES to update the Framework of Indicators to identify any significant
change in previously provided multi-annual management advice ............................................... 24
NASCO has requested ICES to identify relevant data deficiencies, monitoring needs, and
research requirements................................................................................................................... 24
Annex 10.1 Glossary of acronyms ................................................................................................................................... 48
Annex 10.2 References cited ....................................................................................................................................... 52
10.2
10.3
10.4
Stock Summary - Atlantic Salmon from the Northeast Atlantic .................................................................. 58
10.2.1
Supporting information ................................................................................................................ 61
Advice for Atlantic Salmon from North America ........................................................................................ 78
10.3.1
Supporting information ................................................................................................................ 80
Advice for Atlantic Salmon at West Greenland ........................................................................................... 97
10.4.1
Supporting information ................................................................................................................ 99
ICES Advice 2013, Book 1
xiii
BOOK 11
Section
Page
11 TECHNICAL SERVICES ....................................................................................................................................... 1
xiv
11.1
About ICES Technical services ...................................................................................................................... 1
11.2
Answers to requests ........................................................................................................................................ 2
11.2.1
EC
......................................................................................................................................... 2
11.2.1.1 Opinion on modification to the list of deep-sea sharks .................................................... 2
11.2.1.2 Opinion on the outcome of an in Year revision for Northern Hake ................................. 4
11.2.1.3 Response on special management measures for skates and rays ..................................... 5
11.2.2
HELCOM ..................................................................................................................................... 22
11.2.2.1 ICES-organized external peer review of the BALTFIMPA Generic Tool .................... 22
11.2.2.2 ICES-organized external peer review of the BALTFIMPA Generic Tool - Stage Two 27
ICES Advice 2013, Book 1
Preface
This report contains the 2013 ICES advice to the advice recipients regarding marine management issues. The report is
produced by the Advisory Committee (ACOM) providing advice on behalf of the Council.
The Advisory Committee include one designated scientist from each of the ICES member countries and the committee
has an independently elected chair and four vice-chairs. The chair of the Science Committee is member ex-officio. ICES
has invited the competent authorities, which are requesting advice from ICES, and stakeholder groups to be present at
Advisory Committee meetings (whether physical or virtual) in observer capacity.
The advice is developed though a process which is setup to ensure that it is based on the best available science, that it is
independent, peer reviewed and that the process is transparent and considered legitimate by authorities and stakeholders.
The process starts out with expert groups who compiles the relevant data, makes a scientific analysis and provides a report
presenting data, methods and outcomes.
These reports are then peer reviewed by designated groups. The review groups are composed of scientists who are not
members of the expert group under review and who normally do not originate from countries with a strong interest in the
stocks concerned. Some review groups include invited reviewers who are not otherwise involved in the ICES assessment
at all and in some cases recruited from institutions not normally involved with ICES advisory work, including research
institutes from outside the North East Atlantic area. The Expert Working Group chairs assist the review groups. In the
case of analysis which is updated with new annual data, but otherwise following an agreed methodology (typically annual
fish stock assessments), this peer review of methods takes place in benchmark workshops which produce a description of
the agreed methodology and the data to use. This description is then applied for subsequent years by the expert group,
where members of the expert group annually will make an audit of each others work, that methodology described in the
benchmark has been properly implemented.
The advisory text is developed in advice drafting groups guided by a chair appointed by ACOM. ICES Delegates and
ACOM members appoint participants in the advice drafting groups.
ACOM then approves the advice.
Structure of the report
Book 1 explains the conceptual and institutional framework for the assessments and advice. It contains a general
introduction to the ICES advice, and includes general and non-regional advice.
Books 2 - 8 are regional reports covering the following marine ecoregions (Figure 1):
•
Book 2: Iceland and East Greenland
•
Book 3: The Barents Sea and the Norwegian Sea
•
Book 4: The Faroe Plateau Ecosystem
•
Book 5: Celtic Sea and West of Scotland
•
Book 6: North Sea
•
Book 7: Bay of Biscay and Iberian Seas
•
Book 8: The Baltic Sea
Book 9 is a separate chapter for widely distributed and migratory stocks and Book 10 provides information on the North
Atlantic salmon.
Book 11 documents the technical services that ICES has provided to its advice recipients throughout the year.
ICES Advice 2013, Book 1
xv
ACOM members and alternates 2013
ACOM Chair
ACOM Vice-chairs
SCICOM Chair
Belgium
Member:
Alternates:
xvi
Canada
Member:
Alternate:
Denmark
Member:
Alternates:
Estonia
Member:
Alternate:
Finland
Member:
Alternates:
France
Member:
Alternates:
Germany
Member:
Alternates:
Iceland
Member:
Alternates:
Jean Jacques Maguire (Canada)
Carmen Fernandez (Spain)
Han Lindeboom (NL)
John SImmonds (UK)
Mark Tasker (UK)
Manuel Barange (UK)
Steven Degraer (Jan–Jul)
Els Torreele (Aug–Dec)
Kris Cooreman
Daan Delbare
Kris Hostens
Kelle Moreau
Hans Polet
Els Torreele (Jan–Jul)
Ghislain Chouinard
Michel Gilbert
Joanne Morgan
Bernard Sainte-Marie
Morten Vinther
Jesper Boje
Fritz W. Köster
Henrik Mosegaard
Toomas Saat
Henn Ojaveer
Georg Martin
Tiit Raid
Matti Salminen
Eero Aro
Ari Leskelä
Atso Romakkaniemi
Alain Biseau
Michel Bertignac
Mathieu Doray
Philipp Hess
Joel Knoery
Pascal Lorance
Paul Marchal
Christopher Zimmermann
Joachim Gröger
Thomas Lang
Anne Sell
Christian von Dorrien
Björn Steinarsson
Astthor Gislason
Einar Hjörleifsson
Sólveig Ólafsdottir
ICES Advice 2013, Book 1
Ireland
Member:
Alternates:
Latvia
Member:
Alternates:
Lithuania
Netherlands
Member:
Member:
Alternate:
Norway
Member:
Alternates:
Poland
Member:
Alternates:
Portugal
Member:
Alternates:
Russia
Member:
Alternate:
Spain
Member:
Alternates:
ICES Advice 2013, Book 1
Maurice Clarke
Leonie Dransfeld
Ciaran Kelly
Colm Lordan
Evin McGovern
Maris Plikshs (Jan–May)
Didzis Ustups (June–Dec)
Juris Aigars
Janis Birzaks
Anda Ikauniece
Georgs Kornilovs
Didzis Ustups (Jan–May)
Tomas Zolubas
Tammo Bult (Dec–Jun)
Floor Quirijns (Jul–Dec)
Lisette Enserink
Martin Pastoors (Jul–Dec)
Floor Quirijns (Dec–Jun)
Reidar Toresen (Jan–Jul)
Harald Gjøsæter (Aug–Dec)
Bjørn Ådlandsvik (Jan–Jul)
Asgeir Aglen (Jan–Jul)
Harald Gjøsæter (Jan–Jul)
Geir Huse
Jarle Klungsøyr
Cecilie Kvamme (Jun–Dec)
Sigbjørn Mehl (Aug–Dec)
Hein Rune Skjoldal
Jan Erik Stiansen (Aug–Dec)
Einar Svendsen (Jan–Jul)
Else Torstensen
Jan Horbowy
Henryka Dabrowska
Piotr Margonski
Fátima Borges
Ivone Figueiredo
Alberto Murta
Yuri Efimov
Yuri A. Kovalev
Dmitry A. Vasilyev
Javier Pereiro
Pablo Abaunza
Pablo Carrera
Jose Fumega
Elena Guijarro (Sep–Dec)
Santiago Lens
Francisco Velasco
xvii
xviii
Sweden
Member:
Alternate:
United Kingdom
Member:
Alternates:
USA
Member:
Alternate:
Faroe Islands
Greenland
Observer:
Observer:
Massimiliano Cardinale
Michele Casini
Joachim Hjelm
Carl O’Brien
Nick Bailey
Walter Crozier
Alejandro Gallego
Emma Hatfield
Coby Needle
Bill Turrell
Gary Shepherd
Larry Alade
Thomas Noji
Jakúp Reinert
Jesper Boje
ICES Advice 2013, Book 1
1
Introduction, overview and special requests
1.1
About ICES
ICES was established in 1902 as an intergovernmental organisation. The ICES Convention from 1964 outlines the
fundamental purposes of ICES, which are:
to promote and encourage research and investigations for the study of the sea particularly related to the
living resources thereof;
to draw up programmes required for this purpose and to organise, in agreement with the Contracting
Parties, such research and investigations as may appear necessary;
to publish or otherwise disseminate the results of research and investigations carried out under its
auspices or to encourage the publication thereof.
Under the Convention, ICES is concerned with the Atlantic Ocean and adjacent seas, primarily the North Atlantic. Today,
ICES provides the scientific underpinning for most of the regulatory commissions concerned with fisheries and the
environment in the Northeast Atlantic and the Baltic Sea.
ICES has grown from a small body of like-minded researchers to a an organisation involving about 4000 scientists, with
20 Member Countries, including all countries with a coastline to the North Atlantic including the Baltic from the USA in
the west to the Strait of Gibraltar in the East. There are also several Countries from outside this area and non-governmental
organisation which are observers to ICES.
Today the member states and the network of scientists use ICES as a platform to plan and coordinate marine science, to
present and discuss outcomes of marine research, to plan and implement the collection of marine data including planning
of surveys with research vessels, to store and exchange marine data, as an outlet for publication of marine research results
and as an advisory body to provide science-based advice to public authorities with competence regarding marine
management such as environmental policy or fisheries management.
ICES fulfils these functions through an Annual Science Conference, two committees governing the science and the
advisory work (the Science and Advisory Committees), more than 150 working and study groups, several symposia
annually, and a wide range of publications. There is a Secretariat located in Copenhagen, which currently has about 50
full-time professional and support staff.
It is the scientists who participate in ICES activities who generate ICES products. The main products are scientific
information based on research conducted in the Member Countries and scientific advice containing information provided
in a format that can be used by policy-makers. The responsibility for the production of scientific advice rests with the
Advisory Committee.
ICES is requested to provide advice on a range of issues relating to marine policies and management. Requests for advice
may be submitted by public authorities with competence for marine management including:
•
Governments of ICES’ member countries,
•
European Commission (EC)
•
Helsinki Commission (HELCOM),
•
North Atlantic Salmon Commission (NASCO),
•
North East Atlantic Fisheries Commission (NEAFC)
•
OSPAR Commission (OSPAR)
ICES may also on its own initiative draw the attention of competent authorities to marine matters which may require
policy and management attention.
ICES Advice 2013, Book 1
1
ICES works with its advice recipients to find the most effective way of delivering integrated advice. The immediate
delivery of advice is through the ICES internet site and the annual summary of advice is provided in this document that
includes all aspects of ICES’ advice.
2
ICES Advice 2013, Book 1
1.2
Advice basis June 2013
1.2.1
General context of ICES advice
ICES advises competent authorities on marine policy and management issues related to the impacts of human activities
on marine ecosystems and the sustainable use of living marine resources.
Overarching international agreements on exploitation of living marine resources
An important part of ICES advice regards the management of the exploitation of living marine resources. The context for
this part of ICES advice is set by several international agreements and policies:
•
United Nations Convention on the Law of the Sea (UN, 1982 (known as UNCLOS)), which includes a call for
a maximum sustainable yield (MSY) approach to managing fisheries;
•
United Nations Conference on Environment and Development (UN, 1992a (known as UNCED)), including
Chapter 17 of Agenda 21 which highlights a precautionary approach;
•
United Nations Straddling Fish Stocks Agreement of 1995 (UN, 1995 (known as the UN Fish Stocks Agreement
or UNFSA)) and the FAO Code of Conduct for Responsible Fisheries (FAO, 1995), both of which call for a
precautionary approach;
•
Convention on Biological Diversity (UN, 1992b (known as CBD)), which calls for conservation of biological
diversity through an ecosystem approach;
•
Johannesburg Declaration of the World Summit on Sustainable Development (UN, 2002 (known as WSSD)),
which calls for an ecosystem approach and rebuilding fisheries to maximum sustainable yield.
In addition, ICES advice responds to the policy and legal needs of ICES member countries and multinational and
intergovernmental organizations that use the advice as the scientific basis to manage human activities that affect, and are
affected by, marine ecosystems. Some applicable policy and legal instruments are:
•
The Common Fisheries Policy of the European Union (EC, 2002)
•
Communication from the European Commission on Implementing Sustainability in EU Fisheries through
Maximum Sustainable Yield (EC, 2006)
•
The Marine Strategy Framework Directive (EC, 2008)
•
Norwegian Marine Resources Act (Lovdata, 2008 (Lov om forvaltning av viltlevande marine ressursar)),
•
Russian Federal Law on Fisheries and conservation of biological resources in the waters. N 166-P3 20/12/2004
(Anon., 2004)
•
Icelandic Fisheries Management Act (No. 38, 15 May 1990) (Anon., 1990)
•
Faroe Islands Fisheries Management Act (Løgtingslóg nr. 28 um vinnuligan fiskiskap frá 10. mars 1994) (Anon.,
1994)
ICES provides advice in the context of these agreements.
Impacts of human activities on marine ecosystems
Almost all ICES member countries have policies that address the impacts of human activities on marine ecosystems which
have been developed under the above international agreements. These policies may explicitly be framed as an
implementation of an ecosystem approach. An important example is the Marine Strategy Framework Directive (MSFD)
of the European Union (EC, 2008), which is a comprehensive framework for achieving good environmental status (GES)
for European marine ecosystems. The Directive calls for scientifically-based indicators and standards for eleven
descriptors of GES such as Biodiversity, Non-indigenous Species, Commercially Exploited Fish and Shellfish Stocks,
Foodwebs, and Sea-floor Integrity.
The Regional Seas conventions have a role in ensuring the cohesion of assessments within their regions. Both OSPAR
and HELCOM have established specific coordinating platforms for the regional implementation of the MSFD, striving
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for harmonized national marine strategies to achieve good environmental status and implementing their overall agreed
commitment to an ecosystem approach.
The ICES scientific community and ICES advisory services have played a key role in providing scientific guidance to
define GES indicators and standards. The process of developing these indicators and standards at the European level is
ongoing and the process is now being continued by revising current monitoring activities and developing programmes of
measures. The MSFD is an important challenge for the scientific community, and ICES welcomes the MSFD as an
opportunity to apply an ecosystem approach.
Marine spatial planning is envisioned as a key mechanism in achieving GES. The idea is to integrate planning and
management actions across human activities (e.g. fisheries, renewable and non-renewable energy development, mineral
extraction, transportation, tourism, recreation, etc.) to take into account the cumulative impact of all of these activities on
ecosystems. This will require more spatially resolved data on more types of activities, and a better understanding of how
these activities impact ecosystems. It will also require integrated ecosystem monitoring systems where ICES has special
experience to offer in particular on the fisheries surveys side. A draft EU Directive on establishing a framework for
maritime spatial planning and integrated costal management has been released in March 2013.
An ecosystem approach to marine environmental policy, a precautionary approach and an MSY approach regarding living
marine resources are prominent themes of the agreements and policies that set the context for ICES advice. A compilation
of acronyms and terminology used in the ICES advice is available at http://www.ices.dk/advice/icesadvice.asp as
acronyms_and_terminology.pdf.
1.2.1.1
An ecosystem approach to management of the marine environment
An ecosystem approach is intended to contribute to sustainable development. Sustainable development is defined in the
Brundtland Report (WCED, 1987) as development that
“meets the needs of the present without compromising the ability of future generations to meet their own needs.”
An ecosystem approach has been defined in various ways but mainly emphasizes a management regime that maintains
the health of the ecosystem alongside appropriate human uses of the environment, for the benefit of current and future
generations. For example, the 1992 UN Convention on Biological Diversity (UN, 1992b) defines an ecosystem approach
as
“ecosystem and natural habitats management” to “meet human requirements to use natural resources, whilst
maintaining the biological richness and ecological processes necessary to sustain the composition, structure and
function of the habitats or ecosystems concerned.”
The Reykjavik Declaration (FAO, 2001) forms the basis for using an ecosystem approach in the management of the
marine environment:
“… in an effort to reinforce responsible and sustainable fisheries in the marine ecosystem, we will individually
and collectively work on incorporating ecosystem considerations into that management to that aim.”
The World Summit on Sustainable Development (UN, 2002) indicated that States should:
“(30.d) Encourage the application by 2010 of the ecosystem approach, noting the Reykjavik Declaration on
Responsible Fisheries in the Marine Ecosystem 1 and decision V/6 of the Conference of Parties to the Convention
on Biological Diversity”.
An ecosystem approach is expected to contribute to achieving long-term sustainability for the use of marine resources,
including the fisheries sector. An ecosystem approach serves multiple objectives, involves strong stakeholder
participation, and focuses on human behaviour as the central management dimension.
ICES is in the process of regionalizing its advice and building the scientific foundation for regional ecosystem advice.
The methods needed to allow ecosystem advice are being developed by working groups on integrated ecosystem
assessments and will support summaries of ecosystem state and pressures documented in “ecosystem overviews”. These
overviews will focus on ecosystem processes in order to enable ecosystem drivers to be incorporated into traditional fish
stock assessments and to enable operational advice to be given regarding possible measures. This process is necessary for
1
“While it is necessary to take immediate action to address particularly urgent problems on the basis of the precautionary approach, it is
important to advance the scientific basis for incorporating ecosystem considerations, building on existing and future available scientific
knowledge.” Source: Reykjavik Declaration, appendix I, pg. 107. (FAO, 2001).
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ICES Advice 2013, Book 1
ICES to provide robust, contextual and relevant advice on ecosystems. ICES will work closely together with the regional
seas commissions (RSCs), European Environment Agency, and EU/DG Environment, to ensure that our efforts are
supplementing on-going activities.
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1.2.1.2
A precautionary approach in fisheries management
A precautionary approach (PA) is described in the UN Fish Stocks Agreement (UN, 1995) as follows:
“States shall be more cautious when information is uncertain, unreliable or inadequate. The absence of adequate
scientific information shall not be used as a reason for postponing or failing to take conservation and management
measures.”
Annex 2 of the UNFSA contains guidelines for applying a precautionary approach within an MSY framework. To quote:
“The fishing mortality rate which generates maximum sustainable yield should be regarded as a minimum
standard for limit reference points. For stocks which are not overfished, fishery management strategies shall
ensure that fishing mortality does not exceed that which corresponds to maximum sustainable yield, and that
the biomass does not fall below a predefined threshold. For overfished stocks, the biomass which would
produce maximum sustainable yield can serve as a rebuilding target.”
In addition, the guidelines indicate:
•
Precautionary reference points should be used to guide management;
•
Target reference points are intended to achieve management objectives;
•
Precautionary reference points should take account of reproductive capacity, the resilience of each stock, and
the characteristics of fisheries exploiting the stock, as well as other sources of mortality and major sources of
uncertainty;
•
Management strategies shall seek to maintain stocks at, or restore stocks to, levels consistent with previously
agreed precautionary reference points. Such reference points shall be used to trigger pre-agreed conservation and
management action. Management strategies shall include measures which can be implemented when
precautionary reference points are approached;
•
Fishery management strategies shall (a) ensure that the risk of exceeding limit reference points is very low, (b)
initiate actions to facilitate stock recovery for stocks below precautionary reference points, and (c) ensure that
target reference points are not exceeded on average; and
•
When information for determining reference points for a fishery is poor or absent, provisional reference points
shall be set.
Although some aspects of the guidelines are not entirely clear (e.g. the relationship between precautionary and limit
reference points is unclear) or consistent (the fishing mortality rate to achieve MSY is referenced as both a target reference
point and a limit reference point), it is most useful to recognize that MSY and a precautionary approach are
complementary, and this is the spirit in which ICES applies these concepts.
Populations need to be maintained within safe biological limits according to a precautionary approach to make MSY
possible. However, within safe biological limits, an MSY approach is necessary to achieve MSY. Lack of scientific
information should not be an excuse for postponing management action to maintain populations within safe biological
limits and/or to delay implementing a strategy to attain MSY. In a sense, a precautionary approach is a risk-averse concept
intended to avoid unproductive situations while an MSY approach is intended to make the best use of the ecosystem
productivity. A precautionary approach (PA) is a necessary, but not a sufficient condition for MSY. The ICES
precautionary approach (including the methods for estimating PA reference points) is described in more detail in the
introduction of previous volumes of ICES advice (e.g. ICES, 2009b).
1.2.1.3
The maximum sustainable yield concept
Maximum sustainable yield has been a widely accepted objective for fisheries management for many decades. The United
Nations Convention on the Law of the Sea (UN, 1982) notes
“…State(s) must set an allowable catch, based on scientific information, which is designed to maintain or restore
species to levels supporting a maximum sustainable yield (MSY).”
This policy was reaffirmed by WSSD (UN, 2002) which called on States to
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“Maintain or restore stocks to levels that can produce the maximum sustainable yield with the aim of achieving
these goals for depleted stocks on an urgent basis and where possible not later than 2015”.
Maximum sustainable yield is a broad conceptual objective aimed at achieving the highest possible yield over the long
term (an infinitely long period of time). It is non-specific with respect to: (a) the biological unit to which it is applied; (b)
the models used to provide scientific advice; and (c) the management methods used to achieve MSY. The MSY concept
can be applied to an entire ecosystem, an entire fish community, or a single fish stock. The choice of the biological unit
to which the MSY concept is applied influences both the sustainable yield that can be achieved and the associated
management options. For reasons discussed later, implementation of the MSY concept by ICES will first be applied to
individual fish stocks, but even on a single-stock basis MSY can only be reached in a healthy environment.
In practice, MSY depends on:
•
The production of the unit, which describes the relation between productivity and the size of the unit (e.g.,
population biomass), which in turn depends on the growth rates, natural mortality rates, and reproductive rates
of the members of the production unit;
•
Interactions of members within the production unit and interactions with other production units (intra- and interspecific interactions);
•
Environmental conditions (e.g., climate, environmental quality), which affect production, and intra- and interspecific interactions; and
•
Fishing practices and fishery selectivity that determine the size and age composition of the catch (both the
landings and the discards).
Many of the models (mathematical and conceptual) used to estimate MSY and associated parameters typically assume
that factors not explicitly included in the models remain constant or vary around a long term mean. Thus, MSY estimates
are generally conditional on current conditions and assumptions. This assumption is reasonable as long as the analysis
does not attempt to project changes which are very different from the prevailing conditions, or from conditions which
have been observed historically. Marine ecosystems are, however, dynamic and fish stocks will not only change in
response to the fisheries directly targeting them but also to changes in fishing patterns and fishing pressures on their prey
or their predators. ICES considers MSY estimates as applicable only in the short-term and they should be subject to
regular re-estimation. This has implications for the further development of the MSY approach as discussed in the context
of incorporation of ecosystem considerations in ICES advice below (Section 1.2.2.5).
1.2.1.4 ICES approach to fisheries advice: Maximum sustainable yield within a precautionary approach
The ICES approach to fisheries advice integrates a precautionary approach, maximum sustainable yield, and an ecosystem
approach into one advisory framework. The aim is, in accordance with the aggregate of international guidelines, to inform
policies for high long-term yields while maintaining productive fish stocks within healthy marine ecosystems. ICES
recognises that although the advice is based on stock objectives, the method is through the management of fisheries and
changes in stock size are the result of both the changes in the fishery and the environment.
ICES provides fisheries advice that is consistent with the broad international policy norms of the precautionary approach,
MSY, and an ecosystem approach while also responding to the specific needs of the management bodies requesting
advice. A precautionary approach has been recognised as an important basis for fisheries management in all the
jurisdictions advised by ICES. ICES notes that in the past the fisheries for which it provides advice have generally not
been managed with MSY as an objective. The current European Commission policy (EC, 2006) calls for EC fisheries to
be managed according to MSY by 2015. Therefore, the nature of ICES fisheries advice is evolving. The evolution includes
options for a transition process to attain full implementation of an MSY approach by 2015. Ecosystem limitations on
fisheries have typically not yet been identified in management policies in the ICES area. However, as the EU MSFD is
implemented, such limits will be recognized to achieve environmental objectives, especially regarding biodiversity, sea
floor integrity, and food webs. Therefore, harvests may be further modified in consideration of potential fishery impacts
on marine ecosystems beyond the impact on target fish stocks.
ICES considers that a precautionary approach, an ecosystem approach and maximum sustainable yield, are not alternative
strategies but are nested boundaries for the harvesting of living marine resources, where the outer boundary is defined by
a precautionary approach to maintain fish stock productivity (Figure 1.2.1). Considerations of wider ecosystem impacts
and interactions may further modify harvest strategies and not all fishing strategies within these precautionary limits will
lead to the largest long-term yields as MSY is constrained by the prevailing ecosystem considerations.
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MSY
Ecosystem impact
boundary
PA exploitation boundary
Figure 1.2.1
8
Limits to the exploitation of living marine resources that arise from a precautionary approach
regarding single-stock exploitation, an ecosystem approach and an MSY approach, as an
integrated framework of nested boundaries
ICES Advice 2013, Book 1
1.2.2
The Technical basis of the ICES advice
Fisheries management under the above philosophy may be carried out using a variety of approaches involving the
specification and control of both input (numbers of vessels, days at sea) and outputs (catches, landings). Within the
currently agreed European allocation scheme and regulatory framework the primary measure is the output or removals
from the stock. Thus, ICES is typically requested to provide catch advice on a stock-by-stock basis, as fisheries on most
of the stocks for which ICES provides advice are managed using stock-specific total allowable catches (TACs). In practice
most fisheries in the ICES area are currently managed through constraints on landings. Those landings figures could be
deduced from the catch advice based on the assumption that discards will remain a stable incremental factor (as observed
in the recent past) additional to the landings. In many cases, other fishery management measures are used as well, such
as technical regulations (e.g. closed areas, mesh sizes, days-at-sea limitations and minimum landing sizes). To support
the European stock by stock management system, the ICES framework for fisheries advice needs to be applicable to
individual stocks. This does not obviate the need to modify stock-specific advice to take account of technical interactions
(e.g. bycatch in mixed-species fisheries) or of biological interactions (e.g. predator–prey relationship), but the structure
for ICES fisheries advice remains the individual fish stock.
1.2.2.1 Maximum Yield and the Precautionary Approach
Fisheries affect fish stocks through catches which can be expressed in a proportional way as the fishing mortality rate (F)
applied to these stocks. Production of a fish stock is the sum of the population weight (biomass) augmented by the young
each year (recruitment or incoming year class) growth in weight of existing year classes minus the loss of numbers of
individuals from natural mortality. Production can be highly variable but, on average, it is related to stock size (often
expressed as spawning-stock biomass or SSB), which in turn depends on F. That is, for each F, there is a long-term
average production and an average stock size. The relationship between F, production, and stock size is called the
production function. Surplus production at a given F is the catch that can be harvested without changing the average stock
size in the long term. The peak of the production function is MSY, and the fishing mortality generating this peak is FMSY.
Figure 1.2.2 gives a hypothetical production function versus F and Figure1.2.3 shows surplus production versus
spawning-stock biomass.
MSY Reference Points
Yield
SSB
200
400
B MSY
100
300
MSY
50
200
SSB
Yield
150
100
F MSY
0
0
0
0.5
1
1.5
Fishing mortality
Figure 1.2.2
Example of a yield (production) versus fishing mortality (F) for a hypothetical fishery. SSB:
spawning-stock biomass.
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Surplus Production
Surplus Production
100
80
60
40
BMSY
20
0
0
200
400
600
800
SSB
Figure 1.2.3
Example of surplus production versus spawning-stock biomass (SSB) for a hypothetical stock. The
theory is that harvesting around 80 units when the stock is at BMSY would keep the stock in full
reproductive state at an SSB capable of delivering MSY. On the stock at the carrying capacity (800
units of SSB) there is no surplus production, all the production is needed to support the high stock
size. If a fishery begins on a stock at carrying capacity (i.e. the virgin state), the SSB is reduced and
surplus production is generated.
Fishing mortality (F) is the only variable in the production function that can be directly controlled by fisheries
management. Fisheries management cannot control SSB, it can only influence it through F. SSB is also subject to natural
variability that on a year-to-year basis can overwhelm the influence of F. MSY is a long-term average, and the maximum
constant yield that could be taken sustainably would be lower than MSY. Fisheries that harvest variable yields in response
to the natural variability in stock size will be on average nearer to the long term MSY.
Due to the natural variability in SSB, beyond the influence of F, there may be situations where the spawning stock is so
low that a significant risk exists that reproduction is impaired. A precautionary approach implies that fisheries
management in such situations should be more cautious. For stocks where quantitative information is available, a
reference point Blim may be identified as the stock size below which there may be reduced reproduction resulting in
reduced recruitment. A precautionary safety margin incorporating the uncertainty in ICES stock estimates leads to a
precautionary reference point Bpa, which is a biomass reference point designed to avoid reaching Blim. Therefore, when
SSB is above Bpa the probability of impaired recruitment is expected to be low. For short-lived species, the biomass can
fluctuate over the full range between years. A precautionary approach in this situation implies that a minimum stock size,
Bescapement, should remain every year in the sea after fishing (Figure 1.2.4).
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Biomass Reference Points
900
800
MSY Btrigger
or
Bpa
or
MSY Bescapement
Recruitment
700
600
500
400
300
200
100
0
0
100
Blim
200
300
BMSY
400
500
SSB
Figure 1.2.4
Illustration of biomass-based biological reference points. Blim and Bpa are precautionary reference
points related to the risk of impaired reproductive capacity, while MSY Bescapement often equal to Bpa
is used in the advice framework for short-lived species. MSY Btrigger is the parameter in the ICES
MSY framework which triggers advice on a reduced fishing mortality relative to FMSY. BMSY is the
average biomass expected if the stock is exploited at FMSY. Diamonds show the variable recruitment
verses SSB that have been observed over the years. Recruitment can be seen to be generally lower
below Blim.
The ICES framework for fisheries advice recognizes that the characteristics of fish stocks are different, and the
information available on individual stocks also varies.
The ICES approach uses both fishing mortality rates and biomass reference points. In general, FMSY should be lower than
Fpa, (a precautionary buffer to avoid that true fishing mortality is at Flim the rate associated with long term stock decline
and ultimately crash) and MSY Btrigger should be equal to or higher than Bpa. This is appropriate since a precautionary
approach is a necessary boundary to ensure sustainability, but not sufficient, condition for achieving the maximum
sustainable yield implied by the MSY framework.
Although most of the stock for which ICES provides advice are considered in terms of exploitation using fishing mortality
rates, for a very small number of stocks, such as Icelandic cod and saithe and some Nephrops stocks, ICES advises based
on harvest rates (HR) a slightly different measure of exploitation. The HR is defined so that the recommended catch is a
fraction of a reference biomass. The reference biomass can be based on total stock biomass, SSB, biomass above a
minimum size or minimum age. The choice is tailored to the most suitable biomass for the stock concerned. In these cases
the fishery may legitimately catch ages or sizes outside the reference range but the HR is still defined in terms of the
selected reference. The HR can also be defined directly on the size or ages selected in the fishery, in this case the reference
biomass is described as the fishable biomass. In stable fisheries with relatively stable recruitment F and HR can be related
directly to one another. If recruitment is very variable or age or size selection changes in the fishery the relationship can
change. Advising using a HR is most suitable for fisheries that exploit intermittent year-classes such as haddock or where
age information is not available such as Nephrops.
1.2.2.2 ICES stock categories
ICES recognise six main categories of stocks, and application of the ICES framework to each of these categories is
discussed below. ICES has used the following biological and information based categorizations:
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Category 1 – Stocks with quantitative assessments
This type of stock can be considered in two sub categories a) stocks with several year classes contributing to the fishery
that includes stocks with full analytical assessments and forecasts as well as stocks with quantitative assessments based
on production models.; and b) short lived species stocks with quantitative assessments. These are the stocks that have
short life cycles with catches dominated by single year classes. They are not considered data-limited and this category
includes stocks with full analytical assessments and forecasts as well as stocks with quantitative assessments based on
production models.
Category 2 – stocks with analytical assessments and forecasts that are only treated qualitatively
This category includes stocks with quantitative assessments and forecasts which for a variety of reasons are considered
indicative of trends in fishing mortality, recruitment, and biomass.
Category 3 – stocks for which survey-based assessments indicate trends
This category includes stocks for which survey indices (or other indicators of stock size such as reliable fishery-dependant
indices; e.g. lpue, cpue, and mean length in the catch) are available that provide reliable indications of trends in stock
metrics such as total mortality, recruitment, and biomass.
Category 4 – stocks for which only reliable catch data are available
This category includes stocks for which a time-series of catch can be used to approximate MSY.
Category 5 – Landings only stocks
This category includes stocks for which only landings data are available.
Category 6 – negligible landings stocks and stocks caught in minor amounts as bycatch
This category includes stocks where landings are negligible in comparison to discards. It also includes stocks that are part
of stock complexes and are primarily caught as bycatch species in other targeted fisheries. The development of indicators
may be most appropriate for such stocks.
1.2.2.2.1a Long-lived stocks with population size estimates
For stocks with population size estimates, ICES can calculate the catch that will achieve a desired fishing mortality rate.
For most stocks with population size estimates, ICES can also forecast future stock size as a function of catch (i.e. for a
range of catch options). In stocks naturally having several age groups, future stock size is not overly dependent on
recruitment because many older animals exist in the population (unless the stock age composition has been truncated due
to high fishing mortality). When population projections are too dependent on recruitment, projections are less reliable
because recruitment can be variable and difficult to measure or predict.
For long-lived stocks with population size estimates, ICES bases its approach on attaining a fishing mortality rate at, or
below, FMSY.
Annex 2 of the UN Fish Stocks Agreement (UNFSA; UN, 1995 see Section 1.2.1) states that “The fishing mortality rate
which generates maximum sustainable yield should be regarded as a minimum standard for limit reference points. For
stocks which are not overfished, fishery management strategies shall ensure that fishing mortality does not exceed that
which corresponds to maximum sustainable yield, and that the biomass does not fall below a predefined threshold.” The
World Summit for Sustainable Development (WSSD, Johannesburg; UN, 2002) states that “To achieve sustainable
fisheries, the following actions are required at all levels: (a) Maintain or restore stocks to levels that can produce the
maximum sustainable yield with the aim of achieving these goals for depleted stocks on an urgent basis and where possible
not later than 2015.” The first statement refers to FMSY as an upper limit to fishing mortality. From a starting point of
excessive exploitation (until recently this was the case for many stocks in the ICES area), the latter statement can be
considered as an intermediate step towards fulfilling the UNFSA requirements as it establishes an intermediate target for
fishing mortality at FMSY, so that stocks are restored by 2015. Competent authorities advised by ICES have based their
implementation on the WSSD and the interpretation that fishing mortality should be reduced to FMSY by 2015 where
possible (e.g. EC, 2006). The ICES MSY approach is thus based on this interpretation.
In this approach, both fishing mortality and biomass reference points are used; these reference points are FMSY and MSY
Btrigger. The approach does not currently use a BMSY estimate. BMSY is a notional value around which stock size fluctuates
when F = FMSY. Recent stock size trends may not be informative about BMSY (e.g., when F has exceeded FMSY for many
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years or when current ecosystem conditions and spatial stock structure are, or could be, substantially different from those
in the past). BMSY strongly depends on the interactions between the fish stock and the environment it lives in, including
biological interactions between different species.
MSY Btrigger is considered the lower bound of SSB fluctuation around BMSY. It is a biomass reference point that triggers a
cautious response. The cautious response is to reduce fishing mortality to allow a stock to rebuild and fluctuate around a
notional value of BMSY (even though the notional value is not specified in the framework). The concept of MSY Btrigger
evolves from the PA reference point Bpa that ICES has used as a basis for fisheries advice since the late 1990s (see Figure
1.2.4). Bpa is derived from Blim based on the precision of the assessment, often taken as a standard value such that is in
most cases Bpa = Blim*1.4. The evolution in the determination of MSY Btrigger requires contemporary data with fishing at
FMSY to identify the normal range of fluctuations in biomass when stocks are fished at this fishing mortality rate.
The ICES approach as specified in a hypothetical Harvest Control Rule (HCR)),) which shows how the target F should
change with SSB is depicted in Figure 1.2.5.
FMSY-HCR
FMSY
SSB (in the year for
which advice is given)
MSY Btrigger
Figure
1.2.5 Approach shown in the ICES harvest control rule. Vertical axis is fishing mortality (F).
Horizontal axis is spawning-stock biomass (SSB). Dotted section indicates stock below Blim
Conceptually, SSB in the HCR is the estimated SSB at the beginning (or at spawning time) of the year to which the advice
applies (advice year). For example, for an assessment performed in 2012 using data through 2011, the reference SSB will
be the projected SSB at the beginning of 2013. FMSY-HCR is the fishing mortality rate used to calculate a catch option for
the advice year. However, it may not be possible to project SSB to the beginning of the advice year, or the projections
themselves may introduce so much additional uncertainty that it would be better to use a current SSB estimate. In such
cases, the SSB used in the HCR will be the most recent reliable estimate.
Since MSY Btrigger is intended to safeguard against an undesirable or unexpected low SSB when fishing at FMSY, the trigger
reference point should be based on the natural variation in SSB and the assessment uncertainty, once FMSY has been
reached. Ideally, FMSY should take account of selectivity, recruitment, growth, and natural mortality under current or
recent ecosystem conditions, and be derived through stochastic simulations of target F in the context of a harvest control
rule. However, recruitment functions are typically very noisy and poorly defined. It is therefore common to use proxies
for FMSY, such as Fmax, F0.1, M, and F20-40%SPR 2 (Figure 1.2.6). Thus FMSY is used as a generic term for a robust estimate of
a fishing mortality rate associated with high long-term yield. These proxies do not take into account the full range of stock
dynamic directly but attempt to give good approximations to Fmsy where insufficient data is available to carry out a fuller
evaluation. ICES will generally indicate when the advice is based on proxies. Conceptually these proxies have the
following properties
2
F20-40%SPR are fishing mortalities that reduce the life time reproductive output of a year class to 20–40% of the reproductive output without fishing.
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Fmax:
The maximum yield point without accounting for the dependence of recruitment on SSB or its annual variability.
Some stocks have a well defined Fmax at low F that is a good approximation for Fmsy. For other stocks the peak is either
poorly defined at high F or not defined at all and the value is unsuitable. Fmax is sensitive to changes in the selection
pattern / selectivity.
The point where the increase in yield with increasing F is 10% of the rate at very low (around zero) F. This point
F0.1:
is often stable and well defined potentially giving a small reduction in yield relative to Fmsy, but may be quite close to Fmsy
once dependence of recruitment on SSB and is annual variability is included. It is not suitable for stocks with higher
natural mortality.
M:
Fmsy taken equal to natural mortality (M). Most suited to stocks with high natural mortality
F20-40%SPR The fishing mortality that reduces the life time reproductive output of a year class to 20–40% of the reproductive
output without fishing. It is based on a study of a wide range of stock biology. It has characteristics similar to F0.1 but is
sensitive to assumptions of natural mortality as it depends on the unexploited biomass.
Changes in selectivity, growth, natural mortality implies a re-estimation of those reference points.
0.8
120%
Proxy ref. Points
0.7
100%
80%
0.5
Yield/R
SSB/R
0.4
0.3
60%
SSB/R
Yield/R
0.6
40%
0.2
30% SSB/R
0.1
F
0
0
20%
F 30%SPR F max
0.2
0.4
0%
0.6
0.8
1
Fishing mortality
Figure 1.2.6
Illustrations of various proxies for FMSY. For SSB/R 100% is at F = 0. Other numerical values are
illustrative only and will vary from stock to stock.
As an initial option, MSY Btrigger is set at Bpa when this reference point is available, unless there is a sound basis for using
a different value. In the future when there are sufficient observations of SSB fluctuations associated with fishing around
FMSY, the MSY Btrigger should be re-estimated to correspond to the lower bound of the range of stock sizes associated with
MSY. In general, re-estimated values of MSY Btrigger will be higher than Bpa because Bpa forms a lower boundary under
the precautionary approach.
The ICES harvest control rule (Figure 1.2.5) is designed to promote recovery of the stock to the normal range of stock
sizes associated with FMSY when the stock is below this range (i.e. when it is below the MSY Btrigger). For most fisheries,
recovery should theoretically occur at a fishing mortality of FMSY 3. The likelihood and speed of recovery is increased by
reducing F whenever the stock is below the stock size range associated with fishing at FMSY. However, at very low stock
sizes, the normal tendency for stock recovery at F less than or equal to FMSY may not hold. In these cases, the fishing
3
The theory is that fish populations compensate for fishing by increasing their production per unit stock size as stock size decreases. This type of
response is known as compensatory. Production functions typically exhibit compensation. However, it is possible that at low stock sizes, production
per unit stock size decreases as stock size decreases. This type of response is known as depensatory. It is difficult to observe (in part because there are
few observations of stocks at very low stock sizes), but there are mechanisms that potentially result in depensation. Depensation has the potential to
lead to extinction of a population.
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ICES Advice 2013, Book 1
mortality rate derived from the HCR is likely to be so low that fishing may cease anyway. Nevertheless, when the stock
size is so low that recruitment failure is a concern (e.g. well below Blim as estimated for a precautionary approach),
additional conservation measures may be recommended to prevent a further decline. The special consideration given at
low stock sizes is depicted by a broken line in Figure 1.2.5.
Competent authorities receiving ICES advice have adopted several management plans in the spirit of the harvest control
rule described above. When these plans are considered consistent with the precautionary approach and if no competent
authority with a legitimate interest rejects a plan as the basis for the advice, the advice on the first page of the ICES
advisory document will be based on the management plan. Other options will be also included in the body of the advisory
report.
The transition to advice based on reaching FMSY in 2015
Based on policy documents of management authorities and discussions with managers, there is general agreement that
fisheries on the stocks for which ICES is requested to provide advice should be managed according to an MSY approach
by 2015, but the transition should be gradual. Significant progress has been made in recent years developing and
implementing precautionary management plans. Most of these plans are already developed based on delivering high long
term yield and are conceptually similar to exploitation under MSY. These plans should not be jeopardized but they can,
if necessary, be revised to be consistent with an MSY approach (as well as being precautionary). Over the next few years,
ICES will advise on options that take account of this evolving situation.
Although the World Summit on Sustainable Development (UN, 2002) called for stocks to be restored to levels that can
produce MSY by 2015 where possible (which requires that overfishing relative to MSY be ended well in advance of 2015,
but for many stocks it is already too late), this is not the policy of the European Commission (see EC, 2006). The EC and
other management bodies that request advice from ICES have indicated they favour a gradual transition to implementing
an MSY approach. Currently MSFD requires meeting Good Environmental Status (GES) which included F <Fmsy by
2020.
Direct application of the ICES MSY approach
In 2010 ICES introduced an MSY framework for fisheries advice. ICES provides catch options by direct application of
the ICES HCR to give catch for Fmsy and where necessary catch options consistent with the MSY transition scheme.
During the transition period (for advice in 2011–2015) where F is above FMSY and/or current biomass is below MSY
Btrigger, ICES applies a stepwise transition to reach FMSY by 2015. The transition is in equal steps beginning with the year
in which the transition was initiated.
ICES Advice 2013, Book 1
15
Transition scheme
If an estimate or a proxy of FMSY was available, the transition began in 2011 and F was to be reduced in five equal steps.
Consequently, the catch option for 2014 will be:
FMSY-HCR-transition (2014) = Min{0.2 • F (2010) + 0.8 • FMSY-HCR (2014); Fpa}
whereas for 2015:
FMSY-HCR-transition (2015) = Min{0.0 • F (2010) + 1.0 • FMSY-HCR (2015); Fpa}
where F (2010) is the current year estimate of the fishing mortality in 2010 and FMSY-HCR (2014) is according to the ICES
HCR in Figure 1.2.5, being equal to FMSY if SSB in 2014 is at or above MSY Btrigger and reduced linearly if SSB is below.
The FMSY-HCR-transition values are capped at Fpa to maintain consistency with a precautionary approach. The plan for
transition to MSY recognizes that managers requested a gradual transition, although they have not formally agreed to
such a plan.
However, there may be situations where a gradual transition is not appropriate because stock size is low (e.g. below Blim)
and unless fishing mortality is reduced more rapidly the outlook is for a further decline (e.g. as a result of low recruitment).
In such cases, ICES advises on a more rapid transition or application of the FMSY-HCR as soon as possible.
1.2.2.2.1b
Short-lived stocks with population size estimates
The future size of a short-lived fish stock is very sensitive to recruitment because there are only a few age groups in the
natural population. Incoming recruitment is often the main or only component of the fishable stock. In addition, care must
be given to ensure a sufficient spawning-stock size as the future of the stock is highly dependent on annual recruitment.
For short-lived species, estimates or predictions of incoming recruitment are typically imprecise, as are the accompanying
catch forecasts.
For most short-lived stocks, the ICES MSY approach is aimed at achieving a target escapement (MSY Bescapement, the
amount of biomass left to spawn, see Figure 1.2.4), which is robust against low SSB and recruitment failure and includes
a biomass buffer to account for recruitment uncertainty. The yearly catches corresponds to the stock biomass in excess of
the target escapement. No catch should be allowed unless this escapement can be achieved every year.
For some short-lived species, assessments are so sensitive to incoming recruitment that the amount of biomass in excess
of the target escapement cannot be reliably estimated until data obtained just prior to the fishery (or during the fishing
year) have been analyzed. Therefore, an adaptive framework may be applied as follows:
1.
2.
3.
Set a preliminary TAC that ensures a high likelihood of the target escapement being achieved or exceeded. This
preliminary TAC is likely to be considerably below the final TAC (step 3).
Assess the stock just before or during the fishing year, typically based on a survey or an experimental fishery.
Adjust the TAC based on the assessment in step 2, ensuring that escapement is at, or above, the target.
The MSY Bescapement should be set so there is sufficient biomass to provide the ecosystem services of a forage fish species
and a low risk of future recruitment being impaired, similar to the basis for estimating Bpa in a precautionary approach.
For short-lived species, where most of the annual surplus production is from recruitment (not growth), MSY Btrigger and
Bpa might be expected to be similar. Therefore Bpa is a reasonable initial estimate of MSY Bescapement.
1.2.2.2.2
Stocks without population size estimates
Of the more than 200 stocks for which ICES provides advice, ICES (2012a) determined that approximately half do not
have population estimates from which catch options can be derived using the existing MSY framework. Up to and
including 2011, ICES provided qualitative advice regarding the future exploitation of such stocks for which there is either
limited knowledge about their biology or lack of data about their exploitation. Advice recipients have, however, expressed
a strong interest in ICES developing quantitative advice based on the information available. In 2012, ICES has therefore
developed a framework for quantitative advice regarding such stocks. This framework will, as other advice approaches,
be refined in the future.
The principles underlying this framework is that the available information should be used, that the advice to the extent
possible should be based on the same principles as applied for stocks with analytical assessments and catch forecasts, and
that a precautionary approach should be followed. The latter implies that as information becomes increasingly limited
more conservative reference points should be used and a further margin of precaution should be adopted when the stock
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ICES Advice 2013, Book 1
status is poorly known. The margin of risk tolerance is a management prerogative, but in the absence of any proposal by
managers ICES has applied values which are given below.
Unlike the classic fishery management problem of estimating maximum sustainable yield (MSY), fishery analysis on
stocks without quantitative assessments must estimate a yield that is likely to be sustainable. The overall approach adopted
by ICES has been developed under WKLIFE (ICES 2012a) and WKLIFE2 (ICES 2012c) and is explained in ICES report
on the implementation of RGLIFE advice on Data Limited Stocks (ICES 2012c). The majority of the data-limited stocks
have more information available than merely either catch or landings. The starting point for this analysis is therefore a
categorization of the stocks according to the data and analyses that are available. The categorization of stocks is intended
to reflect the decreasing availability of data, and thus the conclusions on the fishing pressure and state of the stock are
likely to be less certain as one goes down the categories.
As a consequence, a precautionary approach implies that exploitation rates advised for stocks below the data rich stocks
(Category 1) will be more conservative than FMSY. Here we provide only a basic overview of the 5 additional categories
that have been defined.
Category 2 – stocks with analytical assessments and forecasts that are only treated qualitatively
A quantitative assessment is available, but for a variety of reasons the information from the assessment has been used
only as a description of trends such as fishing mortality, recruitment, biomass and future catches, rather than as an
analytical assessment. Previously such analytic assessments were presented without Y-axis values. This approach uses a
modification of the HCR from De Oliveira, J.A.A. et al., (2010). The general approach is to apply F0.1 as a robust and
generally precautionary proxy for FMSY to account for the additional uncertainty associated with an assessment that cannot
reliably estimate the size of the stock.
Category 3 – stocks for which survey-based assessments indicate trends
Surveys or other relative abundance or biomass indices are available for these stocks and they provide reliable indications
of trends in total mortality, recruitment and abundance or biomass, but no quantitative, analytic assessment is available
for the stock. The general concept of survey-based catch advice is based on Russell’s (1931) non-equilibrium definition
of overfishing, in which catch exceeds biological production and causes a reduction in the stock. Therefore, decreasing
surveys suggest catch should be incrementally decreased and vice versa.
Category 4 – stocks for which only reliable catch data are available
Only catch or landings data are available, and the data may not be continuous or consistent over time for a variety of
reasons. The approach is to use estimates of Depletion-Corrected Average Catch (DCAC) to give approximations of stock
depletion over the catch time series, it requires the ratio of FMSY/M and M. It assumes that the average catch has been
sustainable in the past if abundance has not changed. Depletion Corrected Average Catch is an approximation of MSY.
However, a catch advice based on MSY is only appropriate for stocks near BMSY (See Figure 1.2.3). For situations in
which DCAC is much greater than recent catch, stock size may be less than BMSY and if F is decreased catch advice should
increase slowly toward DCAC. Decreases or increases in catch are incremental and slow.
Category 5 – Landing only stocks
In the rare situation that only landings data are available, and no relevant life-history or fishery information can be gleaned
from similar stocks or species in the eco-region or beyond the first approach should be to compile as much additional
information as possible on fishery and survey data to transition to another category. However, in the meantime a
Productivity and Susceptibility Analysis (PSA) risk assessment is used to evaluate the risks.
Category 6 – negligible landings stocks and stocks caught in minor amounts as bycatch
This category includes stocks where landings are negligible in comparison to discards. It also includes stocks that are part
of stock complexes and are primarily caught as bycatch species in other targeted fisheries. The development of indicators
may be most appropriate for such stocks.
For each of these categories, methods have been employed to provide quantitative advice in 2012.
Category one accounts for a precautionary approach through the use of PA reference and limit points. In order to apply a
precautionary approach for categories 2-6 the framework for these stocks includes the following considerations regarding
uncertainty and precaution have been applied in sequence:
ICES Advice 2013, Book 1
17
-
-
As the methodologies used to estimate stock status, trends, and forecasts, due to the limited data available, are
expected to be more susceptible to noise than methods used to produce forecasts for data-rich stocks, a change
limit of ±20% (uncertainty cap) has been applied in the advice. This change limit is relative to the reference on
which it is based and may be, e.g. recent average catches or a projection of a trend.
A principle of an increasing precautionary margin with decreasing knowledge about the stock status has been
applied:
o The reference points for exploitation used have, when proxies could be identified, been selected on the
lower margins of FMSY – either at the lower range of an interval as F0.1 or similar.
o A precautionary margin of −20% (precautionary buffer) has been applied for those cases when the stock
status relative to candidate reference points for stock size or exploitation is unknown. Exceptions to this
rule have been made in cases where expert judgement determines that the stock is not reproductively
impaired, and where there is evidence that the stock size is increasing or that exploitation has reduced
significantly – for instance, on basis of survey indices or a reduction in fishing effort in the main fishery
if the stock is taken as a bycatch species.
This approach is intended to move in the direction of sustainable exploitation, having due regard for the species’ biological
characteristics and uncertainty in the information. This implies that advice is applicable to a time-frame which is
compatible with a measurable response in the metrics used as the basis for the advice; i.e. in the simplest case, and where
the least information is available, this would imply a multi-annual constant catch advice. Where least information is
available, including cases where the 20% precautionary margin has been applied, ICES therefore considers that the advice
is not expected to be changed for a fixed and determined period such as, for example, three years, unless important new
knowledge emerges regarding a stock which may justify a revision of the advice.
1.2.2.3
Frequency of advice and updates in 2013
In 2012 most stocks were allocated to categories and advice was provided. Many of these stocks have little new
information on an annual basis and the advice can be used for two or more years.
The 2012 advice will generally not be updated in 2013 if:
o Biennial advice was provided in 2012 (e.g. elasmobranches, deep sea species and nephrops).
o Only landings data are available and changes are negligible (categories 5 and 6 stocks).
o The advice in 2012 was for lowest possible landings or zero catch advice (e.g. some elasmobranches,
Irish sea cod) and there are no changes in the perception of the stock.
o The PA buffer has been applied in 2012, except Pandalus in IIIa and IVa East for which an interbenchmark process is underway and for anchovy in IXa which is a short-lived species.
o The DCAC method (category 4) was applied.
o The advice has been the same for the last 3 years or more and the stock index has changed by less than
10%.
The 2012 assessment and advice may be updated in 2013 if:
o The PA buffer has not been applied and the stock index has declined by more than 10% compared to
that used as the basis of advice in 2012.
o There are doubts about the method applied in 2012 and a more appropriate method can be put forward.
o Benchmarks have been held
1.2.2.3
Ecosystem considerations in fisheries advice
The move toward an ecosystem approach to management (UN, 1992b, 2002; FAO, 1995) implies that human activities
should be managed such that the overall health of the marine ecosystem is not placed at risk. This means that management
of fisheries must consider not only the direct effects on fishery targets, but also the impacts on biodiversity, marine
ecosystem structure, functioning, marine habitats and interactions between the fish populations.
The advice must also be based on the best available knowledge about the interactions between the fish populations and
their environment, be it other fish populations, other organisms, or the physico-chemical environment.
A first step is to incorporate knowledge about the interactions between the various fish populations, for which advice is
given. Two types of interactions should be considered in fisheries management, as described below.
One type of interaction (referred to as “technical interactions”) results from the non-selective nature of many fishing
operations. That is, the fishery captures a mixture of species and it is not entirely possible to control which species and
how much of each is caught. For a mixed-species fishery, it may not be possible to achieve the single-stock MSYs
(translated into TACs) of all the stocks simultaneously. Either the recommended maximum catches for some stocks will
be exceeded in trying to catch the TACs of other stocks, or the TACs for some stocks will not be caught in order to prevent
recommended maximum catches of other stocks from being exceeded. ICES has developed a mixed-species fisheries
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ICES Advice 2013, Book 1
model (ICES, 2009a, 2010). The full value of this model (and future models of this type) will be realized with input from
managers and stakeholders on trade-offs between species in the catch. The choice among different trade-offs and whether
to fish only below or also above Fmsy for the different species in the fishery is not a scientific but a societal issue. However,
ICES does consider that the precautionary approach and Fpa forms an upper bound for exploitation under these conditions.
Estimates of MSY reference points depend on the size and age selectivity of the fishery. In many cases, both a higher
yield and a larger stock size can be obtained by changing fishing practices (e.g. mesh size, fishing area and season) to
achieve more favourable size and age selectivity. However, changing fishing practices to favour one species may put
other species at a disadvantage in a mixed-species fishery. In the future, mixed-species fisheries advice should provide
information to inform trade-offs between species in terms of changes in fishing practices that influence selectivity.
As in 2012 ICES provides catch options in 2013 that incorporate technical interactions regarding demersal fisheries in
the North Sea. The options are given as scenarios and not as the basis for the advice as single-stock management plans
are currently in force, and mixed-fisheries advice would require an agreed policy for mixed-fisheries management by the
relevant authorities.
Another type of interaction results from ’biological interactions‘: some fish eat other fish, which means growth for the
predator and mortality for the prey: fish populations also compete for food or habitat. Such interactions mean that as
populations of one species increase by higher numbers and increased growth, populations of other species are likely to
decrease because their mortality increases due to predation. It also means that as a population of fish increases one cannot
expect that growth and mortality for that species remains constant as there will be increasing competition for food and
habitat within that population. This is what is referred to in ecology as ‘density-dependence’ and is the reason that it is
not realistic to assume simple projections of the growth of biomasses from low population sizes as the fishing pressure is
reduced, for instance towards FMSY. This is also the basic reason for ICES to refrain from defining rebuilding targets based
on a BMSY concept and the reason BMSY is not a part of the ICES approach to MSY.
The implication is that all of the predicted increases in stock size based on applying an MSY approach on an individual
stock basis are unlikely to occur simultaneously. Some stocks will increase substantially, but biological interactions may
prevent other stocks from increasing as much as anticipated, and there may even be stocks that decrease in abundance as
they are predated on by larger predator populations or are exposed to increased competition for food or habitat.
ICES has for a number of years incorporated such multispecies considerations in the single-species framework by
applying natural mortality or growth rates that are derived from models of species interactions using size, age, and
stomach data for several species in Baltic, Barents Sea and North Sea. ICES has routinely incorporated short term changes
in growth and maturation in short term projections in order to account for competition and food supply. ICES also expects
to update MSY reference points regularly (typically as part of the benchmark process) again to reflect current dynamics.
These aspects are a first step toward incorporating species interactions in fish stock assessments and advice and helps in
making short-term predictions, where the surrounding ecosystem can be considered constant for a few years relative to
the stock in question, more accurate. The utility of this approach is, however, very limited when it comes to medium-term
forecasts or the exploration of long term reference points in an ecosystem context because the populations of all the
various fish species are expected to change with changing fishing regimes and the interactions can therefore not be
considered to be constant.
This means that a full-fledged MSY approach cannot be implemented on a stock-by-stock basis. Basic MSY reference
points such as FMSY, BMSY, and MSY Btrigger are conditional on a variable surrounding ecosystem and the other predator
or prey fish populations living in it because growth and natural mortality, both of which are influenced by other fish
populations, are determinants of these reference points.
This means that the references to MSY reference points in UNFSA (UN, 1995) and other international agreements
ultimately must be interpreted as features of the fish community or even the ecosystem rather than as constant parameters
of a fish stock.
Although biological interactions thus are important in terms of the response of stocks to a change in fishing pressure
within a MSY approach, there are relatively few situations where the response of a multispecies community of fish to
changes in fishing mortality can be reliably predicted. In the few cases where such predictions are possible, multispecies
fishing mortality strategies can be developed to achieve MSY on a multispecies basis and to evaluate trade-offs between
species based on preferences from managers and stakeholders. In situations where predictive models accounting for
biological interactions are not reliable, it will be necessary to adopt a stock-by-stock MSY approach based on the observed
response of these stocks once they have been fished at FMSY. As very few stocks have a history of exploitation at MSY
target reference points, biomasses reference points can be expected to evolve as more and information become available.
ICES Advice 2013, Book 1
19
As in 2012 ICES provides considerations in 2013 on options to incorporate biological interactions between herring, sprat,
and cod in the Baltic in advice and fisheries management. The options are not presented as the basis for the advice as
there are single-stock management plans in force, and multispecies fisheries advice would require an agreed policy for
relevant authorities to consider biological interactions in fisheries management. Where relevant ICES indicates which
options are considered precautionary.
Achieving single- or multi-species MSY is not necessarily sufficient to assure all aspects of a healthy ecosystem and may
need to be supplemented with measures to mitigate undesirable impacts on ecosystems. This need for supplementary
measures is also considered in ICES advice. Reducing fishing mortality or changing selectivity should also reduce: (a)
bycatch of non-target and sensitive species; (b) impacts on habitat and biodiversity; (c) the risk of truncated age structure;
and (d) alterations that could possibly affect ecosystem functionality.
In some cases, advice has included considerations of the impacts of fisheries on other components of the ecosystems. An
example is the advice regarding sandeel, which is based on an escapement strategy to ensure that there is sufficient sandeel
biomass to support populations of other biota that feed on sandeel.
Where specific marine environmental management policies exist that require the regulation of fisheries to achieve their
objectives, the fisheries advice will be restricted within the limitations required to achieve these objectives. In the EU
context, this may be the case regarding fishing impacts on habitats relative to the Habitats Directive (Council Directive
92/43/EEC on the Conservation of natural habitats and of wild fauna and flora), and fisheries impacts on biodiversity, sea
floor integrity, and foodwebs relative to the Marine Strategy Framework Directive (Directive 2008/56/EC of the European
Parliament and of the Council of 17 June 2008 establishing a framework for community action in the field of marine
environmental policy). In the NEAFC context, advice has already been provided on fishing practices and fishing
limitations to protect habitats of cold-water corals.
1.2.2.4
Management plan evaluations
Recovery, or long-term, management plans have already been agreed for a number of fish stocks or fisheries within the
ICES area, and new plans are being proposed. ICES has evaluated such management plans according to their compliance
with a precautionary approach regarding risks to maintenance of reproductive capacity, and now also evaluates them
according to the likelihood that high yields will be produced in the longer term. Stakeholders and authorities may raise
other issues that may also be addressed in a specific management plan evaluation, such as stability of yield and risks
under specific recruitment regimes.
ICES has adopted one precautionary criterion for all medium/long lived stocks and a second similar criterion for short
lived species.
–
𝑴𝑴𝑴𝑴𝑴𝑴𝑴𝑴𝑴𝑴𝑴𝑴 𝒐𝒐𝒐𝒐 𝑳𝑳𝑳𝑳𝑳𝑳𝑳𝑳 𝒍𝒍𝒍𝒍𝒍𝒍𝒍𝒍𝒍𝒍:
Management plan is precautionary if the maximum probability that 𝑆𝑆𝑆𝑆𝑆𝑆 is below 𝐵𝐵𝑙𝑙𝑙𝑙𝑙𝑙 is ≤ 5%, where the
maximum (of the annual probabilities) is taken over all years in the plan (i.e. short and long terms), accounting
for modification for recovery plans or initial recovery phases within long-term management plans.
–
𝑺𝑺𝑺𝑺𝑺𝑺𝑺𝑺𝑺𝑺 𝒍𝒍𝒍𝒍𝒍𝒍𝒍𝒍𝒍𝒍
(a) If under natural conditions of no fishing the long-term annual probability of SSB being below 𝐵𝐵𝑙𝑙𝑙𝑙𝑙𝑙 is ≤ 5%, then
the same criteria as for medium or long lived species is used.
(b) If under natural conditions of no fishing, the long-term annual probability of SSB being below 𝐵𝐵𝑙𝑙𝑙𝑙𝑙𝑙 is > 5%,
then the management plan is precautionary if the maximum probability that SSB is below 𝐵𝐵𝑙𝑙𝑙𝑙𝑙𝑙 is ≤ 5% (after
the fishery) in any year when a fishery takes place. In all other years the fishery should be closed. Accepted plans
with the above or more stringent criteria should not imply an increase of the long-term annual probability of SSB
being below 𝐵𝐵𝑙𝑙𝑙𝑙𝑙𝑙 by more than a factor of 2 compared to natural conditions of no fishing.
The management plans in place by 2012 were generally agreed prior to the introduction of MSY in the ICES advice, and
on the basis of plan compliance with a precautionary approach. Some plans have since been evaluated with regard to
generating high long-term yields, and these plans are considered also to be in accordance with an MSY approach.
While the probability of avoiding a limit point should be less than 5%, ICES considers that a target point is reached if the
associated probability of being above or below is 50%.
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ICES Advice 2013, Book 1
It is generally anticipated that in the future competent authorities will aim at management plans (or replacement of
management plans) being consistent with MSY. Management plan evaluations will be conducted to determine how plans
perform in terms of long-term average catch, average stock size, average fishing mortality rate, and the statistical
distributions of these variables. The ICES HCR will be used as a reference in comparing plan performance, although
ICES does not expect that this HCR is superior to other HCRs, as it is selected to provide a simple approach with only
the magnitude of yield as a consideration. Unless managers agree on specific performance criteria, the management plan
evaluation can only be comparative; that is, ICES would not recommend one plan over another and would have no basis
for rejecting a management plan if it is consistent with an MSY approach and it does not violate the precautionary
approach.
1.2.3
ICES processes to provide stock status and single-stock advice
ICES uses specific terminology and symbols or pictograms to describe the status of stocks. The wording aims at using a
nomenclature which is less prone to misinterpretation, but at the same time allows for a match to the legal description,
which still uses “safe biological limits“. ICES discontinued the use of this wording in 2008 as “safe biological limits” has
in some cases misled the recipients of ICES advice and other stakeholders to consider stocks described as being “outside
safe biological limits” to be biologically threatened (i.e. close to extinction).
The terminology now uses different wording for the description of the stock status for biomass and fishing mortality and
for the comparison to reference points based on an MSY approach, a precautionary approach, and existing and
implemented management plans. The structure and the associated symbols and text are given below in Table 1.2.1 and
12.2.2 for MSY and precautionary approaches:
Table 1.2.1 Symbols and text for MSY status
MSY reference points
Fishing mortality (FMSY)
Biomass (MSY Btrigger)
Explanation
F < FMSY and
Sign
Text
Appropriate
F <<< FMSY (~ 0)
Below target
F > FMSY
Above target
No reference point
Undefined
Stock status unknown
Unknown
SSB = MSY Btrigger or
SSB > MSY Btrigger
SSB < MSY Btrigger
At trigger or Above trigger
No reference point
Undefined
Stock status unknown
Unknown
Below trigger
Table 1.2.2 Symbols and text for precautionary status
Precautionary
reference points
Fishing mortality (Fpa,Flim)
Biomass (Bpa,Blim)
Explanation
Sign
Text
F =< Fpa
Harvested sustainably
Flim > F > Fpa
Increased risk
F > Flim
Harvested unsustainably
No reference point
Undefined
Stock status unknown
Unknown
SSB ≥ Bpa
Full reproductive capacity
Blim < B < Bpa
Increased risk
SSB < Blim
Reduced reproductive capacity
No reference point
Undefined
Stock status unknown
Unknown
In the case of management plans, the terminology changes depending on the characteristics of a specific reference point;
namely, if the reference point is considered a target or a limit. If considered a target, this reference point would usually
come with a target range, which means that a green symbol can be used when the stock is within the estimated or defined
range, although for most of the stocks a range has not been defined. It is necessary to identify whether the reference points
are defined as targets or as limits for each individual plan.
Table 1.2.3
Symbols and text for status of stocks fished under management plans.
ICES Advice 2013, Book 1
21
Management plan 4
reference points
Fishing mortality (FMP)
Biomass (SSBMP)
Explanation
Sign
Text
F< F mgt target / limit
Below target /Below limit
F within defined range
At target or Within target range
F>F mgt target / limit
Above target / limit
SSB > target, limit or trigger biomass
Above target/limit/trigger
SSB within defined range
At target or Within target range
SSB < target, limit or trigger biomass
Below target/limit/trigger
In situations where very limited information is available and the stock status table is filled with grey question mark
symbols, ICES provides additional, qualitative information where available. For example, this information could be
based on survey information and give an indication of stock status or trend.
Table 1.2.3
Symbols and text for stocks with limited information.
Qualitative evaluation
Fishing mortality or
exploitation rate
Biomass
If only trends are known
Explanation
Sign
Text
If there is an idea of the exploitation of this stock in relation to any possible reference points:
If F is very high i.e. F > possible
Short description
reference points
If F is very low i.e. F < possible
Short description
reference points
If there is an idea of the state of this stock in relation to any possible reference points:
If SSB is very low, i.e. SSB < possible
Short description
reference points
If SSB is very high i.e. SSB > possible
Short description
reference points
If parameter increases
Increasing
If parameter decreases
Decreasing
If trend is stable
Stable
The production of ICES advice can be separated into four distinct temporal phases (Figure 1.2.7):
•
•
•
•
The first phase is the assembly of data up to December 31st of the year preceding the assessment year.
The second phase is the assessment of the state of the stock at 1 January of the assessment year, This phase is
looking at the past only and dealing with the stock status.
The third phase between the assessment and the forecast is the assessment (interim) year. As incomplete data are
available for this year (the year is not over yet), ICES has to make a number of assumptions on the fishery and
biology. Some of these so-called interim year assumptions can significantly influence the catch forecast for the
next year, but these assumptions are uncertain. If these assumptions prove to be markedly different from reality
in subsequent assessments, stock status may be different than that forecasted.
The fourth phase is the prognosis (forecast) on catch options to be taken next year (the year for which advice is
given) and the state of the stock resulting from the different options.).
Figure 1.2.7
Timeline of the production of ICES advice
In some cases where stocks are short-lived (see above) this three phase approach is compressed into two years with catch
options provided for the current year for in year management.
The framework for the statement regarding future fisheries (third phase) has been developed in consultation with the
relevant competent authorities. From among the range of catch options presented ICES provides a single main advice
option which is based on the following principles:
4
Only included when plan is considered consistent with PA by ICES and agreed on by all relevant clients
22
ICES Advice 2013, Book 1
1.
2.
3.
1.2.4
If competent authorities with an interest in the stock have agreed that a management plan can be the basis for
advice and this management plan has been found to be precautionary, this management plan will be the basis for
the ICES advice.
If this does not apply, the advice will be based on the ICES MSY framework.
If there is no basis for giving MSY-based advice, advice will be based on precautionary considerations (see
introductory section to the 2009 advice report).
Advice to inform an ecosystem approach to marine management
At the 13th Dialogue Meeting between ICES and the Clients (ICES 2004), the ICES plans for the introduction of an
ecosystem approach into the advice were discussed.
In 2008 ICES provided ecosystem overviews for the different sea regions (ICES, 2008). In 2012, these reviews will be
updated starting with the Baltic Sea region. A new approach will be included in which an ecosystem description is
combined with long-term trends in specific species or groups of species, and with long-term trends in drivers of ecosystem
change such as climate and fishing pressure. Depending on the availability of long-term data, these overviews will be
made available for the different ecoregions during 2013 and 2014.
The organisation of the advisory report in ecoregions facilitates an ecosystem approach to marine management which is
currently narrowly focussed on fisheries management. In future, non-fisheries parts of the trophic chains will be
considered and integrated into advice going beyond fisheries management; e.g. aspects of eutrophication in the Baltic Sea
linked with the abundance of the top predator cod.
Our understanding of the functioning of the ecosystems is confined to certain ecosystem components. Work is underway
to expand the number of ecosystem components beyond fisheries that are included in the ICES advice. However, this
understanding is not uniform among ecosystems; some ecosystems have more data and the critical processes are
understood better than in other ecosystems.
Sources
Anon. 1990. Icelandic Fisheries Management Act (No. 38, 15 May 1990).
Anon. 1994. Faroe Islands Fisheries Management Act (Løgtingslóg nr. 28 um vinnuligan fiskiskap frá 10. mars 1994).
Anon. 2004. Russian Federal Law onfFisheries and conservation of biological resources in the waters. N 166-P3
20/12/2004.
Beddington, J. R., and May, R. M. 1977. Harvesting Natural Populations in a Randomly Fluctuating Environment.
Science, 197 (4302): 463–465 (DOI: 10.1126/science.197.4302.463).
De Oliveira, J.A.A., Darby, C.D., Earl, T.J. and C.M. O'Brien. 2010. Technical Background Evaluation of Annex IV
Rules. ICES CM 2010/ACOM:58: 28 pp.
EC. 2002. Council Regulation (EC) No. 2371/2002 of 20 December 2002 on the conservation and sustainable exploitation
of fisheries resources under the Common Fisheries Policy.
EC. 2006. Implementing sustainability in EU fisheries through maximum sustainable yield. Communication from the
Commission to the Council and the European Parliament. COM (2006) 360 (final).
EC. 2008. Directive 2008/56/EC of the European Parliament and of the Council of 17 June 2008 establishing a framework
for community action in the field of marine environmental policy (Marine Strategy Framework Directive).
FAO. 1995. Code of Conduct for Responsible Fisheries. FAO Fisheries Technical Paper 350.
http://www.fao.org/WAICENT/FAOINFO/FISHERY/agreem/codecond/codecon.asp.
FAO. 2001. Reykjavik Conference on Responsible Fisheries in the Marine Ecosystem. Iceland, 1–4 October 2001.
http://www.refisheries2001.org/.
ICES. 2004. Report of the Thirteenth ICES Dialogue Meeting: Advancing scientific advice for an ecosystem approach to
management: collaborating amongst managers, scientists, and other stakeholders. Dublin, Ireland, 26–27 April
2004. 2004. ICES Cooperative Research Report, 267.
ICES. 2008. Report of the ICES Advisory Committee 2008. ICES Advice, 2008.
ICES. 2009a. Report of the Ad hoc Group on Mixed Fisheries in the North Sea (AGMIXNS), 3–4 November 2009. ICES
CM 2009/ACOM:52.
ICES. 2009b. Report of the ICES Advisory Committee 2009. ICES Advice, 2009. Book 1: Introduction, Overviews and
Special Requests.
ICES. 2010. Report of the Working Group on Mixed Fisheries Advice for the North Sea (WGMIXFISH), 31 August–3
September 2010. ICES CM 2010\ACOM:35.
ICES. 2012a. Report of the Workshop on the Development of Assessments based on LIFE history traits and Exploitation
Characteristics (WKLIFE), 13-17 February 2012, Lisbon, Portugal. ICES CM 2012/ACOM:36. 121 pp. (in prep.)
ICES 2012b. ICES implementation of advice for data limited stocks in 2012. Report in support of ICES advice. ICES
CM 2012/ACOM:68.
ICES Advice 2013, Book 1
23
ICES 2012c Report of The Workshop to Finalize the ICES Data-limited Stock (DLS) Methodologies Documentation in
an Operational Form for the 2013 Advice Season and to make Recommendations on Target Categories for Data
limited Stocks (WKLIFE2) ICES CM 2012/ACOM:79
Lovdata. 2008. Lov om forvaltning av viltlevande marine ressursar LOV-2008-06-06-37. http://www.lovdata.no/all/hl20080606-037.htmlhttp://www.lovdata.no/all/hl-20080606-037.html.
Russel F. S. (1931). Some theoretical considerations on the “overfishing” problem. J Cons. Cons. Int. Explor. Mer. 6(1)
3-27
Sissenwine, M. P. 1978. Is MSY and adequate foundation for optimum yield? Fisheries, 3: 22–42. (doi: 10.1577/15488446(1978)003<0022:IMAAFF>2.0.CO;2).
UN.
1982.
United
Nations
Convention
on
the
Law
of
the
Sea
(UNCLOS).
http://www.un.org/Depts/los/convention_agreements/convention_overview_convention.htm.
UN. 1992a United Nations Conference on Environment and Development (UNCED), Rio de Janeiro, Brazil.
http://www.un.org/esa/dsd/agenda21/res_agenda21_00.shtml.
UN. 1992b. Convention on Biological Diversity. http://www.cbd.int/convention/text/.
UN. 1995. United Nations Conference on Straddling Fish Stocks and Highly Migratory Fish Stocks.
http://www.un.org/Depts/los/convention_agreements/convention_overview_fish_stocks.htm.
UN. 2002. World Summit on Sustainable Development (WSSD), Johannesburg, South Africa.
http://www.un.org/jsummit/html/documents/summit_docs.html.
WCED. 1987. Our Common Future. Report of the UN World Commission on Environment and Development 1987
http://www.un-documents.net/wced-ocf.htm.
24
ICES Advice 2013, Book 1
1.3
Technical basis for the advice
The conceptual basis for the ICES advice on fisheries management is described in section 1.2 of this report. This section
describes the technical basis for the advice including data and assessments.
1.3.1
Data used and data quality
Catch and effort data
The quality of the fish stock assessments is closely linked to the quality of the fisheries data, and ICES has expressed the
greatest concern over the quality of catch and effort data for some of the important fisheries in the ICES area.
The stock assessments presented in this report are carried out using the best possible estimates of the total catch. These
estimates are not necessarily identical with the official landings statistics because they may include estimates of
unreported landings and corrections for misallocation of catches by area and species. In the past there have been problems
associated with discrepancies between the official landing figures reported to ICES by member countries and the
corresponding catch data used by ICES. ICES recognises the need for a clear identification of the categories of the catch
data. ICES attempts to identify factors contributing to the total removals from the various stocks through:
•
recorded landings,
•
discards at sea,
•
slipping of unwanted catches,
•
losses due to burst nets, etc.,
•
unreported landings,
•
catch reported as other species,
•
catch reported as taken in other areas,
•
catch taken as bycatch in other (e.g. industrial) fisheries.
The discards, slipped fish, unreported landings and industrial bycatches may vary considerably between different stocks and
fisheries. It may not always be possible to reveal the sources of the estimated removals because of restrictions on how the
data has been made available to ICES (e.g. confidentiality clauses). As a minimum, ICES describes the origin of the data
(sampling programmes, field observations, interviews, etc.) so that interested parties can evaluate the quality of the
information. Estimates of by-catches from the industrial fisheries are included in the assessments wherever the data is
available. In recent years more information on discards has been collected through observer programmes and this information
is increasingly made available to ICES for assessment purposes..
The catch data used by ICES are collated on a stock basis and not on an area basis so that direct comparisons between
these figures and the official statistics are not always appropriate.
ICES attempts to correct the shortcomings in the catch data. For non-reported landings such corrections, by their very
nature, are difficult to document and are obviously open to debate. The stock assessments that are based on these data are
of poor quality but they are still expected to be the best possible assessment of the state of the stocks. The fishing industry
has on various occasions strongly disagreed with ICES’ estimates and has blamed ICES for not performing well. ICES
does not accept the responsibility for quantifying non-reporting fisheries or ensuring access to proper discard data. The
responsibility for discards and non-reporting and the uncertainty regarding the extent of these phenomena rests with the
national authorities and the industry.
When catch data could not be estimated, the trends in the stocks have sometimes been evaluated using research vessel data.
This will only allow relative trends to be estimated and cannot be translated into a numerical advice on removals or effort. .
Research vessel data
Research vessel surveys are an essential fishery-independent source of information for scientists and a vital cross-check
to the figures gathered from the international landings and from sampling onboard fishing boats. On research vessel
surveys, scientists sample demersal fish such as cod, haddock, hake and plaice or pelagic fish such as mackerel and
herring.
ICES Advice 2013, Book 1
25
To sample fish on or near the seabed scientists use bottom trawls in the same way that fishers do. But whereas fishers
target hotspot areas and continually try to upgrade their fishing gear to maximise their catch, fisheries scientists don’t
want to maximise their catch but instead collect a representative sample. They also have to compare their results with
previous years to follow trends, so it is vital that they use the same standard fishing gear each year rather than continually
improving it.
Research vessel surveys are carried out by national research institutes. ICES has an important role in internationally
coordinating and analysing the surveys.
Information from the fishing industry
There is an increasing interaction between scientists and fishers during the collection of data in harbours and through
observer programmes onboard fishing vessels. There have been a number of joint research projects between the fishing
industry and scientists that have aimed to collect additional information on e.g. catch rates or catch compositions. In
recent years, fishers in the North Sea have also been filling in questionnaires recording their perception of the state of key
fish stock. This information is considered during the process of deriving ICES advice.
Commercial Catch per Unit Effort (CPUE) series have been used in several stocks assessment as an indicator of stock
abundance. In most cases the catch is then disaggregated by age through a market sampling process. A major difficulty
in the use of CPUE series in stock assessment is the standardisation of fishing effort. The increasing efficiency of fishing
vessels (e.g. through technical developments, GPS devices, new gear materials etc.) needs to taken into account in an
estimate of effective fishing effort. This is not always possible due to lack of the relevant data for standardisation.
The collaborations between the fishing industry and scientists has provided information which has been included as part
of the assessment process. Such information has contributed to the understanding of the fisheries, and is increasingly
provided in a form which enables direct inclusion in quantitative assessments.
1.3.2
Assessing the status of fish stocks
Stock sizes and fishing mortalities are estimated in a stock assessment model. Most stock assessment models use catch at
age information from the commercial fisheries and use additional information to “calibrate” the assessment. The
additional information is mostly research survey indicators or catch rates in the commercial fishery (CPUE information).
The estimated catches can be subject to serious bias if there are significant amounts of unreported landings or when
information on discards at sea is not available. Catch information tends to become most unreliable when management
measures are most restrictive (if they were implemented). In recent years several stocks have been at a low level and catch
information has deteriorated for many fisheries. The consequence is that the ability to provide reliable, quantitative catch
forecasts has decreased.
Most management strategies in the ICES area rely on some forecast of the outcome of fisheries management in the
management year. Under these conditions the Management Option table is an important part of the ICES advice. The
catch options rely on estimates of recent stock size and fishing mortality and require an assumption about the total catch
in the current or “assessment” year, because the fishery is rarely over when the assessment is carried out.
1.3.3
Evaluations of management plans
When fisheries management plans have been agreed or proposed, ICES will evaluate the consistency of the management
plan with international agreements and commitments. The main comparison will be in relation to the consistency with
the precautionary approach.
The methods for evaluating management plans differ by area, species and type of plan, but the general characteristics are
that both fish populations and the management measures are simulated in a computer simulation process. The results of
the simulations are scored in relation to the probability with which the stocks would be expected to be below Blim in near
to medium term future.
If the evaluation of a management plans indicates that a stock has a low probability (e.g. less that 5%) of being below Blim
in the medium term, ICES considers the plan in accordance with the precautionary approach even when the stock is below
the precautionary biomass level (Bpa) or above the precautionary fishing mortality (Fpa).
1.3.5
Quality of the advice
ICES is dedicated to being transparent on the quality of the advice. Since 2004 competent authorities and a number of
stakeholder organization are invited as observers to reviews and the advisory committee meetings. The quality of the
26
ICES Advice 2013, Book 1
advice can further be assessed by information in the advice on the basis for the advice relating to the subsequent years
and, for stocks where analytical assessments could be carried out, a comparison between the most recent assessment and
the previous assessments.
ICES Advice 2013, Book 1
27
1.4
Structure of the Report
The ICES advisory report is based on a regional orientation in so-called “Ecoregions” that allows the further development
of an ecosystem approach in European waters. A review of existing biogeographical and management regions against a
series of evaluation criteria has demonstrated that no existing regions could be adopted as ecoregions (ICES, 2004 5). The
proposed ecoregions (Figure 1) are based on biogeographic and oceanographic features and existing political, social,
economic and management divisions:
• Iceland and East Greenland Seas
• Barents Sea
• Faroe Plateau Ecosystem
• Norwegian Sea
• Celtic Sea and west of Scotland
• North Sea
• South European Atlantic Shelf – Bay of Biscay and Iberian Seas
• Baltic Sea
• Oceanic northeast Atlantic
The ecoregions Barents Sea and Norwegian Sea are presented in one single volume (3).
The map also shows regions that are not covered by the ICES Advisory Report
• Mediterranean Ecoregions:
o Western Mediterranean Sea
o Adriatic-Ionian Seas
o Aegean-Levantine Seas
• Black Sea
The widely distributed and migratory species and the deepwater species for which stock identity have not been
established, are addressed in Volume 9.
The North Atlantic salmon stocks that are of interest to the North Atlantic Salmon Commission (NASCO) are treated in
Volume 10.
5
ICES. 2004. Report of the ICES Advisory Committee on Fishery Management and
Advisory Committee on Ecosystems, 2004. ICES Advice. Volume 1: 115–131.
28
ICES Advice 2013, Book 1
Figure 1.4.1
Proposed ecoregions for the implementation of the ecosystem approach in European waters,
combined with ICES areas.
ICES Advice 2013, Book 1
29
1.5
Answers to non-Ecoregion specific Special Requests
1.5.1 EU DG Mare
1.5.1.1
Special request, Advice April 2013
ECOREGION
SUBJECT
General advice
Request from EU concerning monitoring of bycatch of cetaceans and other
protected species
Advice summary
1.
Monitoring schemes. Sampling under the Data Collection Framework (DCF) can contribute to the assessment
of bycatch of cetaceans and other species, but is not sufficient on its own as currently implemented by Member
States. Not all fisheries are adequately covered and many issues, including design and sampling protocols would
need to be modified/extended if DCF monitoring was to be the sole source of information. Monitoring under
Regulation 812/2004 is much more specific for cetaceans, and has included the use of dedicated observers and
remote electronic video recording. Development of remote electronic video recording seems likely to be a costeffective way of assessing bycatch in the future.
2.
Acoustic Deterrent Devices (ADDs). ICES advises that regulation should not inhibit the development of more
effective devices to deter harbour porpoises and other marine mammals from fishing gear. The characteristics of
existing ADDs, which can deter harbour porpoises from fishing gear, are known. These characteristics cannot
though be used to define all effective devices. Further studies would be needed to define standards for harbour
porpoises and for ADDs that would be effective for other marine mammal species. To allow further development
of ADDs, ICES recommends that a performance standard should be set. For an ADD to become acceptable, it
should have a proven ability to reduce bycatch of the relevant species in the setting of a commercial fishery.
3.
Reference points. Robust methods for setting reference points for bycatch of protected species already exist.
ICES recommends that a process involving both managers and scientists be established to set species- and, where
relevant, population-specific reference points. ICES proposes that a Bycatch Risk Approach be used to classify
fisheries in terms of risk to protected species.
Request
ICES has been requested by EU to respond to the following request:
“1. Assess the extent to which current fishery monitoring schemes, including inter alia those conducted under
the DCF and Regulation 812/2004, provide an acceptable means of assessing the nature and scale of
cetaceans and other protected species bycatch. Consider alternative means and other sources of data that
could be used to improve our understanding of the conservation threat posed to cetaceans and protected
species by bycatch in European fisheries.
2.
Advise on how Annex II of Regulation 812/2004 defining technical specifications and conditions of use
Acoustic Deterrent Devices could be best revised in light of technical and scientific progress in this field.
3
Based on the methodology used and the estimates of bycatch limits (take limits) generated by region at
WKREV812 and other relevant analyses, propose effective ways to define limits or threshold reference
points to bycatch that could be incorporated into management targets under the reformed CFP. Limits or
threshold reference points should take account of uncertainty in existing bycatch estimates, should allow
current conservation goals to be met, and should enable managers to identify fisheries that require further
monitoring, and those where mitigation measures are most urgently required.”
In the context of this request, ICES interprets “protected species” as those marine species listed in the relevant annexes
of the Habitats Directive. The advice may also be relevant to bycatches of other marine species. ICES will be providing
further advice on the bycatch of seabirds later in 2013.
Elaboration of the advice
1.
30
Monitoring schemes. Sampling under the DCF tends to focus on the metiers that discard the most fish; these are
not necessarily the same metiers that have the largest catch of protected species. Thus, bottom trawling is
ICES Advice 2013, Book 1
generally oversampled with respect to monitoring of protected species bycatch, while in some specific fishing
areas setnets, longlines, and purse-seines are undersampled. Some Member States have also undertaken
additional observation schemes to meet the requirements of Regulation 812/2004 and those of the Habitats
Directive (92/43/EEC). It would be possible to better define requirements on Member States under the DCF, but
much will depend on how other data collection requirements will change under the revised Common Fisheries
Policy. Alternatives to monitoring by human observers on-board vessels could include remote electronic video
recording (e.g. Remote Electronic Monitoring), monitoring from vessels visiting a fishing fleet, interviews, and
fishers’ logbooks. Indications of a bycatch problem may be obtained through schemes that examine stranding of
protected species on shorelines. Of these alternatives remote electronic video recording seems to have the
greatest potential to be developed to meet many of the needs of the existing DCF and also to improve monitoring
of bycatch of protected species.
2.
Acoustic Deterrent Devices. The standards currently listed in Annex II of Regulation 812/2004 are not fully
appropriate. ICES advises that several commercially available ADDs have been proved effective in deterring
harbour porpoises from fishing gear under specified conditions of use in commercial fisheries (Table 1.5.1.1).
Other ADDs with the same specifications (and usage conditions) are therefore likely to be effective. It should be
noted that many of these specifications are linked – thus for example, a higher source level ADD would not need
to be spaced as close to another ADD as one with a lower source level. Some ADDs have been used to deter
other species, and in some cases their efficacy for these species has been demonstrated. It is assumed that ADDs
with similar key properties are as effective as those that have been tested. ICES recommends that ADDs targeted
at reducing bycatch for these other species and under further development for harbour porpoises should only be
authorised under Regulation 812/2004 if they have been proven by rigorous experiment to reduce bycatch rates
by at least 80% with a 95% confidence. Experiments should be conducted in such a way that parties with a vested
interest in the results cannot influence outcomes; they should include at least one control group and one treatment
group. Experiments should be covered 100% by independent on-board observations and bycatch rates should be
based on statistically independent bycatch events.
Table 1.5.1.1
Overview of commercially available ADDs that have proven effective in deterring harbour porpoises
from fishing gear. ADDs listed in italics do not have a published study of their effectiveness, but
have the same specification as those with such a study.
ADD type
Source levels
dB re 1 μPa
rms at 1 m
Signal frequency
(kHz)
Pulse
duration
(nominal)
Interpulse
interval
(s)
Dukane Netmark
1000
Fumunda 10 kHz
Aquamark 300
Aquamark 100
132
10
300 ms
4
Maximum
distance between
any netting and
the nearest ADD
200 m
132
132
145
10
10
20–160
300 ms
300 ms
200–300 ms
4
4
5–30
100 m
100 m
455 m
DDD-03 L
174
5–500
0.5–9 s
Random
4 km
DDD-03 N
174
5–500
0.5–9 s
Random
4 km
3.
Reference
Gönener and
Bilgin (2009)
Larsen and
Krog (2007)
Northridge et
al. (2011)
Reference points. Several methods have been used in defining limits or threshold reference points to bycatch of
cetaceans (Table 1.5.1.2). The robustness of the various models to uncertain information varies. All rely on a
public authority to define the overall conservation objective in terms that can be used in mathematical models,
so their derivation requires not just the input of scientists, but also of relevant authorities. ICES cannot therefore
provide advice on limits or threshold reference points, but instead recommends that the European Commission
establishes a process involving both scientists and managers to derive these limits, using the most appropriate of
these approaches for populations of species believed to be at most risk from bycatch. ICES advises that harbour
porpoise, and common, striped, and bottlenose dolphin populations appear to be the species most at risk from
bycatch in European waters at present.
Table 1.5.1.2
Existing procedures to set limits and reference points for bycatch of marine mammals.
Algorithm
Catch Limit Algorithm (CLA)/Revised
Management Procedure (RMP)
ICES Advice 2013, Book 1
Management framework
International Whaling
Commission
Conservation
objectives
72% carrying capacity
on average
(50% of the time)
Simulation
timeframe
100 years
31
Potential Biological Removal (PBR)
1.7% of best available population estimate
USA under Marine Mammal
Protection Act
ASCOBANS (for harbour
porpoises in non-depleted areas)
50% of carrying capacity
(95% of the time)
80% of carrying capacity
(95% of the time)
100 years
100 years
ICES advises that a Bycatch Risk Approach be used to identify areas and fisheries posing the greatest likely conservation
threat to cetacean species due to bycatch (Figure 1.5.1.1). This approach can also be used for protected species other than
cetaceans. The approach splits the population numbers of each protected species into different Management Areas (MA)
and calculates take limits of species by area for any bycatch threshold level used. By using an expected bycatch rate
(numbers per day or per unit of catch) multiplied by the total fishing effort, an approximate total number of bycaught
animals can be estimated for each fishery and compared with any proposed take limit (see above).
Figure 1.5.1.1
The Bycatch Risk Approach.
Basis of advice
1.
Monitoring schemes. The Data Collection Framework (DCF) is currently undergoing review and revision and
will become the Data Collection Multi-Annual Programme (DCMAP). DCMAP will guide future fishery
monitoring and data collection within the EU, covering a broad range of objectives. The contents of DCMAP
are not yet determined, so ICES bases this advice on the current DCF as it seems likely that the principles will
apply also to DCMAP. One of the current uncertainties in the DCMAP is the forthcoming EU ‘discards ban’ and
how this will be implemented in detail. This ban may have profound consequences for fisheries monitoring in
future. It could, for example, result in much greater emphasis on port-based sampling schemes, rather than seagoing observer schemes. It seems likely that bycatch of protected species will continue to be discarded and
returned to the sea as they are “non-commercial” and unlicensed possession of such species is illegal in most EU
Member States.
In formulating the advice, ICES compared the coverage of current sampling under the DCF and the EU
Regulation 812/2004 programmes with known abundances of cetaceans (and approximate indications of
abundances of other protected species), with an index of bycatch vulnerability and with minimum estimates of
fishing effort by metier (ICES, 2013b). Metiers/areas were identified where the risk to populations of certain
species (groups) being adversely affected was greatest, and where coverage of the present monitoring schemes
was relatively poor.
2.
32
Acoustic Deterrent Devices. Information was extracted from a recent review of the effectiveness of Acoustic
Deterrent Devices (Dawson et al., 2013). ICES also approached a small number of underwater acousticians and
manufacturers of ADDs and asked them for their views on how Annex II of Regulation 812/2004 could be best
revised. A number of existing ADDs are effective in reducing harbour porpoise bycatch, but the full bounds of
the technical specifications between an effective and an ineffective ADD are not known. ICES considers
important that in advising on effective ADD specifications, there should be no constraints on the development
of more effective devices for harbour porpoises or devices effective in deterring other species. ICES thus
recommends that rigorous experiments are needed to demonstrate the effectiveness of new ADDs, while
prescriptive constraints are unhelpful. ICES bases its advice for an >80% reduction in bycatch on the results of
all the successful pinger experiments listed by Dawson et al. (2013), with a minimum confidence level of 95%
as suggested/used for scientific studies.
ICES Advice 2013, Book 1
3.
Reference points. ICES has reviewed the existing procedures to establish limits and reference points (CLA, PBR,
and 1.7%) several times in the past decade (SGFEN, 2002a, 2002b; ICES, 2012b). In all cases it was found that
the choice of the most appropriate procedure depended on choices by managers in defining precisely the
conservation objectives. These objectives essentially describe a societally chosen balance between exploitation
of resources and conservation of protected species. The most appropriate way of working is therefore jointly
between managers and scientists to explore and define conservation objectives. Furthermore, the choice of the
most appropriate procedure to be adopted to achieve the conservation or management goal should be driven by
the availability of suitable data.
Sources
Dawson, S. M., Northridge, S., Waples, D, and Read, A. J. 2013. To ping or not to ping: the use of active acoustic devices
in mitigating interactions between small cetaceans and gillnet fisheries. Endangered Species Research, 19:
201−221.
Gönener, S., and Bilgin, S. 2009. The effect of pingers on harbour porpoise, Phocoena phocoena, bycatch and fishing
effort in the turbot gill net fishery in the Turkish Black Sea coast. Turkish Journal of Fisheries and Aquatic
Sciences, 157: 151−157.
ICES. 2010. Report of the Workshop to evaluate aspects of EC Regulation 812/2004 (WKREV812). ICES CM
2010/ACOM:66. 65 pp.
ICES. 2012a. Report of the Study Group on Practical Implementation of Discard Sampling Plans (SGPIDS). ICES CM
2012/ACOM:51. 81 pp.
ICES. 2012b. Report of the Working Group on Marine Mammal Ecology (WGMME). ICES CM 2012/ACOM:27. 140 pp.
ICES. 2013a. Report of the Working Group on Bycatch of Protected Species (WGBYC). ICES CM 2013/ACOM:27.
83 pp.
ICES. 2013b. Report of the Workshop on Bycatch of Cetaceans and other Protected Species, 2013 (WKBYC). ICES CM
2013/ACOM:36. 41 pp.
Larsen, F., and Krog, C. 2007. Fishery trials with increased pinger spacing. Paper presented to the Scientific Committee
of the International Whaling Commission. IWC SC/ 59/ - SM2, International Whaling Commission, Cambridge.
Northridge, S., Kingston, A., Mackay, A., and Lonergan, M. 2011. Bycatch of vulnerable species: understanding the
process and mitigating the impacts. Final report to Defra, Project MF1003. 99 pp. Available at:
http://randd.defra.gov.uk/Document.aspx?Document=MF1003-FINALRevisedAugust2011.pdf
SGFEN. 2002a. Incidental catches of small cetaceans. Report of the meeting of the subgroup on fishery and the
environment (SGFEN) of the Scientific, Technical and Economic Committee for Fisheries (STECF), Brussels,
10–14 December 2001. SEC (2002) 376. 83 pp.
SGFEN. 2002b. Incidental catches of small cetaceans. Report of the second meeting of the subgroup on fishery and the
environment (SGFEN) of the Scientific, Technical and Economic Committee for Fisheries (STECF), Brussels,
11–14 June 2002. SEC (2002) 1134. 63 pp.
ICES Advice 2013, Book 1
33
1.5.1.2
ECOREGION
SUBJECT
Special request, Advice June 2013
General advice
New information regarding the impact of fisheries on other components of
the ecosystem
Advice summary
ICES advises that the following seven areas contain habitats sensitive to bottom fishing activities:
Hebrides Terrace Seamount;
Rosemary Bank Seamount;
Porcupine Sea Bight;
Faroe–Shetland Channel and Tampen area;
Irish Margin/Bay of Biscay;
Gulf of Cadiz;
Northwest Rockall Bank.
Request
Provide any new information regarding the impact of fisheries on other components of the ecosystem incl. small cetaceans
and other marine mammals, seabirds and habitats. This should include any new information on the location of habitats
sensitive to particular fishing activities. [Memorandum of understanding between the European Union and the
International Council for the Exploration of the Sea, 2013].
ICES advice
The advice in this section covers new information on the location of habitats sensitive to particular fishing activities (i.e.
vulnerable marine ecosystems, VMEs). Advice on the impact of fisheries on seabirds is being collated under the heading
of another special request from the European Commission that will be answered in the second half of 2013. The focus of
ICES work in 2013 on bycatch of marine mammals and other components of the marine ecosystem has been more towards
reviewing and advising on an improved monitoring and assessment system. This has been advised upon already to the
European Commission (on 25 April 2013; ICES, 2013a). The only new data available to ICES in 2013 on the issue of
bycatch is that contained in Member States’ reports to the Commission under Regulation 812/2004. ICES considers that
no new issues have arisen as a consequence of the information in those reports.
New information on the location of habitats sensitive to particular fishing activities
New data that indicate the presence of VMEs were submitted to ICES in 2013 (ICES, 2013b). Some of these data were
within the EEZs of Member States of the EU.
ICES has no information (i.e. VMS data) available on actual fishing activity in these areas at the spatial resolution required
to evaluate the pressure on the habitats.
1) Hebrides Terrace Seamount
The Hebrides Terrace Seamount lies to the west of the UK, being partially joined to the continental slope. The summit is
around 1000 m and the steep-sided flanks descend to below 2000 m. In 2012 a research survey completed two ROV
(Remotely Operated Vehicle) transects of the steep flanks of the seamount and one transect across the summit. On the
seamount summit, three ROV still images contained VME indicator species and none were at densities that would indicate
actual VMEs. On the steep flanks, however, between the depths of 1200 m and 1700 m, coldwater corals were consistently
observed at high densities, indicating VMEs (Figure 1.5.1.2.1).
34
ICES Advice 2013, Book 1
Figure 1.5.1.2.1
Observations of VME indicators on the Hebrides Terrace Seamount.
2) Rosemary Bank Seamount
The Rosemary Bank Seamount lies at the north end of the Rockall Trough. In 2012 a trawl sample was obtained from the
lower muddy slope on the eastern side of the bank at a depth of around 1300 m (59.245°N; −9.525°W). A large bycatch
(>1000 kg) of Geodia sponges (a species vulnerable to bottom fisheries) was taken.
3) Porcupine Sea Bight
Positions of deep-sea sponge aggregations reported by Rice et al. (1990) have become available. These were collected
during scientific trawl surveys at depths between approximately 1000 and 1500 m (Figure 1.5.1.2.2).
ICES Advice 2013, Book 1
35
Figure 1.5.1.2.2
Positions of deep-sea sponges in the Porcupine Seabight area.
4) Faroe–Shetland Channel and Tampen area
A recent (2011) trawl bycatch record of a deep-sea sponge aggregation (estimated weight >1000 kg) confirms the northern
part of the Faroe–Shetland Channel and Tampen area as important for deep-sea sponge habitat (Figure 1.5.1.2.3).
Figure 1.5.1.2.3
36
Positions of deep-sea sponge observations in the Tampen area. The red circle indicates the new
observation.
ICES Advice 2013, Book 1
5) Whittard Canyon (Irish Margin)
ROV transects found VMEs throughout the Whittard Canyon along with dead coral rubble fields (Figure 1.5.1.2.4). VME
indicator species observed included Schizopathidae, Carophyliidae, Gorgonacea, Alcyoniidae, Paragorgiidae,
Chrysogorgiidae, Isididae, Stylasteridae, Primnoidae, and Pennatulacea.
Figure 1.5.1.2.4
Positions of VME indicator species in the Whittard Canyon.
6) Gulf of Cadiz (Spain)
There are cold-seeps and mud-volcanoes on the Guadalquivir Diapiric ridge in the Gulf of Cadiz (36.5°N; −7.25°W).
These VMEs are at depths of approximately 550 m and therefore potentially at risk from bottom fishing activity.
7) Northwest Rockall Bank
Rockall Bank is a large plateau that lies partly in EU waters and partly in international waters regulated by NEAFC. Six
further video transects revealed extensive patches of coral reefs in the centre and toward the southern end of the current
closure (Figure 1.5.1.2.5). Another video transect revealed new observations of coral reefs outside the eastern part of the
closure. No VMEs were observed along a transect to the north of the closure.
ICES Advice 2013, Book 1
37
Figure 1.5.1.2.5
Map of Northwest Rockall showing locations of video transects and new findings of VMEs.
References
ICES. 2013a. Report of the ICES Advisory Committee 2013. ICES Advice, 2013. Book 1, Section 1.5.1.
ICES. 2014b. Report of the ICES\NAFO Joint Working Group on Deep-water Ecology (WGDEC), ICES CM
2013/ACOM:28. 370 pp.
Rice, A. L., Thurston, M. H., and New, A. L. 1990. Dense aggregations of a hexactinellid sponge, Pheronema carpenteri,
in the Porcupine Sea Bight (northeast Atlantic Ocean), and possible causes. Progress in Oceanography, 24: 179–
196.
38
ICES Advice 2013, Book 1
1.5.1.3
Special request, Advice December 2013
ECOREGION
General advice
SUBJECT
EU request on monitoring of bycatch of seabirds
Advice summary
ICES advises on a series of fisheries where bycatch is likely to pose a risk to seabird populations. Fisheries within each
of the four European DCF regions as well as some parts of the larger DCF areas were reviewed for level IV métiers.
Information on bycatch remains relatively sparse and is becoming increasingly dated. Priority should be given to
monitoring in trammelnets and set gillnets in the Baltic, North Sea, and North Atlantic, and in set long-line fisheries in
the Atlantic and Mediterranean/Black Sea.
A framework, including metrics and criteria, to define a seabird bycatch problem is described and explored. Further work
would be needed to assess the risk of bycatch adversely affecting seabird populations if this framework was adopted.
A standard data format is under development and the database developed by ICES for marine mammal bycatch is designed
also to store seabird bycatch data.
Request
The European Commission (DG MARE) requests ICES to consider the following:
•
•
•
To review and update current seabird bycatch data and identify fisheries where appropriate follow up
monitoring to establish bycatch levels would be desirable.
To explore the criteria and/or metrics that could be used to define a seabird bycatch problem. (This request is
partially addressed in earlier request by the Commission to ICES on cetacean bycatch) but ICES should tailor
this advice to specifically cover seabird bycatch.
Establish a standard data reporting format for recording seabird bycatch and develop a database of seabird
bycatch data in EU fisheries, similar to the database developed by WGBYC for marine mammal bycatch.
ICES advice
1.
Fisheries where appropriate follow-up monitoring to establish bycatch levels would be desirable
Table 1.5.1.3.1 lists those fisheries for which ICES advises that bycatch of seabirds should be monitored. Fisheries are
specified at métier level 4 (gear type) for each of the DCF regions Baltic Sea, North Sea, North Atlantic, and
Mediterranean Sea/Black Sea. Only those fisheries are listed where bycatch of seabirds is known or at least can be
suspected. The decision on whether to recommend monitoring in individual fisheries was based on one of these situations:
•
•
Information/data already exist that indicate seabird bycatch. This information might originate either from
dedicated seabird bycatch monitoring schemes, from data collected during the DCF observer programmes, or
from specific projects on seabird bycatch.
Expert judgement determines that bycatch could be suspected/expected/is likely in this particular fishery. This
judgement could be based either on anecdotal information about seabird bycatch, or on transfer of knowledge
about the same fishing method from other marine areas. It could also be based on biological information, for
instance that life habits (such as foraging strategies) of similar bird species make interactions with the specific
fishing method likely.
In Table 1.5.1.3.1, countries were named only to indicate where information about seabird bycatch comes from. For most
regions, it can be assumed that any bycatch occurring in one fishing fleet is likely to occur in similar fleets of other
countries using the same gear. It is likely that there is variance in risk at a sub-regional scale due to variation in bird
occurrence and in location of fisheries. Any bycatch recording scheme that is being established should, if possible, take
account of any knowledge of such variation.
If monitoring for seabird bycatch is indicated in the table as desirable, this does not necessarily mean that a full and
regular monitoring scheme should be implemented. In many cases, especially where seabird bycatch is only suspected,
the first step could be to run specific monitoring pilot projects to gain better knowledge about the amount and extent of
seabird bycatch. It should also be noted that the status of seabird populations has not been taken into account; monitoring
of bycatch in an increasing population may be less urgent than in a decreasing population. Analysis of existing information
ICES Advice 2013, Book 1
39
on causes of mortality (e.g. from returns of seabirds that have been marked and found dead) may also be useful in
prioritizing monitoring.
40
ICES Advice 2013, Book 1
Table 1.5.1.3.1
Gear types where bird bycatch is known or suspected and ICES advice on the desirability of monitoring. Colours in the gear type cells symbolize level of activity: orange – common
fishing gear/activity in this ecoregion; green – negligible or non-existent; white – not known. In the ”Bird bycatch” column, “Yes” means data exist and ”Suspected” means expert
judgement has been applied, with the justification for this judgement being summarized in the final column. An orange colour in the ”Monitoring desirable” column indicates a
monitoring priority based on likely scale of bycatch.
Baltic
Gear type
Bird bycatch
Monitoring
desirable
Remarks and rationale for monitoring
Drifting longlines
[LLD]
Set longlines [LLS]
Suspected
Yes
Yes
Yes
Pots and traps [FPO]
Suspected
Yes
No data are available on bycatch of birds in the Baltic, but susceptible species that occur in the Baltic are caught
elsewhere in this gear.
Bycatch has been recorded in fisheries targeting flatfish, cod, flounder, and eel in German waters; the species
caught include great cormorant, auks, and seaduck.
Evidence from elsewhere indicates that bycatch of species such as great cormorant can occur.
Fykenets [FYK]
Yes
Yes
Great cormorants have been recorded as drowning in fykenets in Danish waters.
Stationary uncovered
poundnets [FPN]
Yes
Yes
This gear is used on all Baltic coasts. A low bycatch of great cormorant has been reported in Denmark,
Germany, and Sweden.
Trammelnet [GTR]
Set gillnet [GNS]
Yes
Yes
Bycatch in gillnets and trammelnets (most studies of seabird bycatch do not distinguish between the two) has
been found to be high and possibly unsustainable in a number of Baltic countries. Diving birds that are affected
include divers, grebes, great cormorant, seaduck, and auks.
ICES Advice 2013, Book 1
41
North Sea
Gear type
Bird bycatch
Monitoring
desirable
Remarks and rationale for monitoring
Bottom otter trawl
[OTB]
Yes
No
Small numbers of common guillemots have been caught in sandeel trawls in the North Sea during the seabird
breeding season; this fishery is short in duration.
Midwater otter trawl
[OTM]
Set longlines [LLS]
Yes
Yes
Northern gannets have been caught in the herring trawl fisheries off the northern and northeastern coasts of the
UK.
Suspected
Yes
No data are available on bycatch of birds in set longlines, but species that occur in the North Sea are caught in
this gear elsewhere.
Fykenets [FYK]
Yes
Yes
Great cormorants have been recorded as drowning in fykenets in Dutch waters.
Stationary uncovered
poundnets [FPN]
Yes
Yes
Three species of auk have been recorded bycaught in UK J- and T-nets targeting salmon and sea trout; that
fishery is closed if bycatch gets too high. High levels of seabird bycatch have also been noted further north in
UK.
Trammelnet [GTR]
Set gillnet [GNS]
Yes
Yes
From the 1980s, bycatch of many thousands of seaduck and great crested grebe birds has been recorded off the
Netherlands; despite mitigation measures, bycatch still occurs. There are few recent data but bycatch of seaduck
and diving seabirds still occurs in UK waters and possibly also off Sweden, Germany, and Denmark where
similar fisheries operate.
Driftnet [GND]
Yes
No
Bycatch of great cormorants, northern gannets, gulls, and common guillemot has been recorded in the UK
bycatch monitoring scheme, notably in salmon and sea trout fisheries off Northumberland and Yorkshire. This
fishery is being phased out.
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ICES Advice 2013, Book 1
North Atlantic
Gear type
Bird bycatch
Monitoring
desirable
Remarks and rationale for monitoring
Bottom otter trawl
[OTB]
Midwater otter trawl
[OTM]
Yes
Yes
Yes
Yes
Midwater pair trawl
[PTM]
Trolling lines [LTL]
Yes
Yes
Suspected
Yes
Drifting longlines
[LLD]
Set longlines [LLS]
Yes
Yes
Yes
Yes
Pots and traps [FPO]
Yes
Yes
Bycatch, including common guillemot, razorbill, and great cormorant, occurs regularly in the seabass fishery in
the western Channel off the UK and France. Some bycatch of gulls occurs in the French anchovy fishery.
There are no data on bycatch from the EU albacore fishery that operates mainly in the Bay of Biscay; seabird
bycatch occurs in trolling operations elsewhere.
Low bycatch, including northern gannet, shearwaters, and yellow-legged gull occurs in fisheries targeting tuna
and other large fish in the waters of Spain, Portugal, and France.
Throughout the region, fisheries targeting a wide range of fish species bycatch many species of seabird, in some
cases in substantial numbers – for example tens of thousands of northern fulmar and great shearwater. Both
surface-feeding birds such as gulls and diving seabirds such as cormorants and auks are affected.
There is some bycatch of European shags in Spain.
Fykenets [FYK]
Suspected
Yes
Great cormorants have been recorded as drowning in fykenets in other waters.
Trammelnet [GTR]
Set gillnet [GNS]
Yes
Yes
There is a regular and widespread bycatch that includes auks, shearwaters (notably Balearic shearwater),
northern gannet, cormorants, seaduck, and divers.
Driftnet [GND]
Suspected
Yes
Purse seine [PS]
Yes
Yes
Beach and boat seine
[SB] [SV]
Yes
Yes
Small driftnet fisheries in the UK and France target a range of fish species. The available information indicates
no bycatch in these, but bycatch does occur in driftnets in other regions and the species affected also occur in the
North Atlantic.
Bycatch, especially of Balearic shearwaters occurs in the Portuguese fishery during the non-breeding period.
Seabird mortality has also been reported in the Spanish fishery.
Bycatch of common scoter (and black-headed gull) has been recorded in the Portuguese fishery. The common
scoter has an important wintering area off the Portuguese coast.
ICES Advice 2013, Book 1
Bycatch has been recorded in Spanish, Portuguese, and French waters in multispecies fisheries. The species
caught include northern gannet, gulls, shearwaters, and cormorants.
Bycatch has been recorded in the Portuguese seabass fishery. Bycatch of northern gannets has been recorded in
the argentine fishery off northwestern UK, and also in fisheries to the west of the UK targeting herring,
mackerel, and horse mackerel.
43
Mediterranean Sea and Black Sea
Gear type
Bird bycatch
Monitoring
desirable
Remarks and rationale for monitoring
Bottom otter trawl
[OTB]
Yes
Yes
Some bycatch of Balearic shearwater, northern gannet, and gulls occurs in the Spanish multispecies fisheries.
Trolling lines [LTL]
Yes
Yes
Scopoli’s and Yelkouan shearwaters are bycaught in the Ionian and Aegean Seas respectively, and there is a
bycatch of Mediterranean shag in the Ionian Sea.
Drifting longlines
[LLD]
Yes
Yes
Bycatch has been recorded mainly in the western Mediterranean. The swordfish fishery has bycatches of
principally Scopoli’s shearwater, but also Balearic shearwater and yellow-legged gull are bycaught. In the
eastern Mediterranean Scopoli’s shearwater has been bycaught. No bycatch has been recorded in the Aegean and
no information is available for certain parts of the Mediterranean (e.g. the Adriatic).
Set longlines [LLS]
Yes
Yes
Bycatch of seabirds including shearwaters (Balearic, Yelkouan, Scopoli’s), Audouin’s gull, Mediterranean gull,
yellow-legged gull, Mediterranean shag, black-legged kittiwake, and skuas occurs in various fisheries targeting
mainly hake, Sparidae, and other demersal fish.
Pots and traps [FPO]
Yes
Yes
Mediterranean shag is bycaught in Spanish lobster fishing; no information for other parts of the Mediterranean.
Trammelnet [GTR]
Set gillnet [GNS]
Driftnet [GND]
Yes
Yes
Bycatch has been recorded of a wide range of seabird species, including Mediterranean shag and great
cormorant, seaduck, razorbill, Yelkouan (and potentially Balearic) shearwaters, and Scopoli’s shearwater.
Suspected
Yes
Bycatch of species that occur in the Mediterranean has been reported in other areas for this gear.
Purse-seine [PS]
Yes
Yes
Bycatch of Balearic (and potentially Yelkouan) shearwaters has been reported in Spanish fisheries for sardine,
anchovy, and other small pelagics.
Beach and boat seine
[SB] [SV]
Recreational fisheries
Suspected
Yes
Bycatch of species that occur in the Mediterranean has been reported in other areas for this gear.
Yes
Yes
Bycatch of Mediterranean shag, shearwaters, and Audouin’s gull has been reported in Spain and Greece
(particularly hand and pole, trolling lines).
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ICES Advice 2013, Book 1
2.
Criteria and/or metrics that could be used to define a seabird bycatch problem
What is a bycatch problem for seabirds?
The definition of what constitutes a problem is of course societal rather than scientific. Societal choices can be derived
from legislation and internationally agreed guidelines. In Europe, Directive 2009/147/EC on the conservation of wild
birds (the Birds Directive) is the most important statute. This sets an overall objective for bird populations: “Member
States shall take the requisite measures to maintain the population of the [bird species] at a level which corresponds in
particular to ecological, scientific and cultural requirements, while taking account of economic and recreational
requirements, or to adapt the population of these species to that level. (Art. 2).” In only a very few cases is the population
of a seabird species believed to be too great, so it may be assumed that bycatch that causes a population decline is a
problem, and for a number of cases where a species is believed to be depleted, bycatch that overly affects the ability of a
population size to recover may also be a problem.
In addition to the “legislative” approach above, public perception of waste and unnecessary death is relevant; thus in the
case of oil spills, most members of the public regard this as a waste (both of oil and of seabirds) that is unnecessary as oil
spills can largely be prevented or avoided. Seabird bycatch does not have the same public profile as oil spills (partly
because it is characteristically chronic and continuous, as compared with the episodic and catastrophic nature of high
profile oil spills). It is also the case that it is difficult to prevent or avoid some seabird bycatch if some particular fisheries
are to continue. It is likely that a high (but not biologically important) bycatch in a fishery where mitigation is possible
would be regarded as wasteful and as a problem. This would be consistent with the General Principles section of the FAO
Code of Conduct for Responsible Fishing, whereby “States and users of aquatic ecosystems should minimize waste, catch
of non-target species, both fish and non-fish species, and impacts on associated or dependent species.”
Framework, criteria, and metrics for defining whether bycatch poses a problem to a seabird species
As indicated in the IPOA (International Plan of Action)–Seabirds and reiterated by FAO (2008), there are key
considerations in identifying whether or not a seabird bycatch problem exists:
“When defining a seabird incidental catch problem, States and RFMO/As [Regional Fisheries Management
Organisations/Arrangements should consider the following:
(i)
(ii)
(iii)
(iv)
Defining the rationale for determining if a problem does, or does not, exist. The rationale should be based
on: (a) the magnitude of seabird bycatch (rate or number); (b) species that are incidentally caught, and
their conservation status; and (c) spatial and temporal overlap of fishing effort with seabirds.”
Reviewing available data relevant to the incidental mortality of seabirds.
Validating sources of information and where appropriate follow up with more detailed investigations.
Adopting a precautionary approach where information is lacking or uncertain.”
ICES advises that these considerations, when taken broadly and in combination with one another, provide sufficient
criteria for defining a seabird bycatch problem when applied within a step-wise assessment framework. ICES advises that
the application of Potential Biological Removal (PBR) may be utilized to serve as the primary metric for determining
whether a seabird bycatch problem exists.
PBR is derived from a formula that combines information on the maximum annual recruitment rate of populations, a
conservative estimate of population size, and a recovery factor.
PBR = ½ RMAX × Nmin × f
RMAX is the maximum annual recruitment rate, Nmin is a conservative estimate of population size (e.g. the 20th percentile
of the population estimate), and f is a recovery factor usually between 0.1 and 1. RMAX can be estimated from the annual
adult survival rate in the absence of human effects and the average age at first breeding. The recovery factor f is usually
set in categories relating to the amount by which a population is believed to be depleted or is declining and can be
designated by broad taxonomic groups, as has been done for marine mammals (in the USA) to account for differences in
their life histories.
ICES advises the following assessment framework (Figure 1.5.1.3.1) be used in the identification of a seabird bycatch
problem, based upon whether or not seabird bycatch is a substantial portion of the anthropogenic impact that causes losses
greater than PBR of a particular species or population. ICES suggests that as a criterion “a substantial portion” could be
interpreted as when bycatch exceeds 30% of anthropogenic mortality to the species or population. ICES is aware of some
projects to evaluate the relative contribution of bycatch to overall anthropogenic mortality, but these projects are rare.
Further information may be available from analyses of the causes of death of ringed birds.
ICES Advice 2013, Book 1
45
Does Total Mortality
Exceed PBR by Species
or Population?
Initial/Risk Assessment
No
Yes
Is a Substantial Portion
of the Mortaliy from
Fisheries?
No
Yes
Mitigation Measures
Figure 1.5.1.3.1
Maybe
Collect
Information/Increase
Monitoring
A proposed framework for exploring the criteria and metrics that could be used to define a seabird bycatch
problem.
Stage 1: The PBR (metric) for each seabird species or population is calculated, using suitable proxies where there is
insufficient information for each species or population.
Stage 2: Once the PBR has been calculated, an initial rapid assessment (similar to a risk assessment) should be conducted
to determine whether, based on existing information (including inferred information) there is a risk that the total estimate
of anthropogenic mortality exceeds the PBR, and whether bycatch is a substantial portion of that mortality. The
information to be used for this assessment may include (but is not limited to):
•
•
•
•
•
•
observations of bycatch,
the results of interviews and/or questionnaires,
information regarding the nature of the fishery interactions,
the geographic overlap between a given species and a fishery/gear type,
information regarding non-fisheries-related mortality, and
inferred information regarding the likelihood of certain species interacting with one or more fisheries.
If the initial assessment results in a determination that it is not likely that PBR has been exceeded for all anthropogenic
mortality, then a seabird bycatch problem does not exist for this species or population. No further immediate action needs
to be taken. ICES recommends that this initial assessment be conducted per species/population at least every five years.
If the initial assessment results in a determination that it is likely that PBR has been exceeded and fisheries are contributing
a substantial portion of the removals, then a seabird bycatch problem may exist for this species or population. In this case,
a third step is recommended.
Stage 3: A more detailed evaluation of existing information, possibly including further studies to verify the existing data
and to further examine the nature and magnitude of the interactions, should be conducted. If this more detailed analysis
confirms that the total estimate of anthropogenic mortality exceeds the PBR, and that bycatch is a substantial portion of
that mortality, then a determination would be made that a seabird bycatch problem exists for this species. ICES
recommends that bycatch mitigation measures for all involved fisheries should be considered and put into effect as rapidly
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ICES Advice 2013, Book 1
as possible. If the results of the more detailed study are ambiguous, it can be reaffirmed that a bycatch problem may exist.
In these circumstances, ICES recommends that additional information, through scientific study or through monitoring, be
collected. The results of these efforts will provide additional information from which to conduct future assessments of
whether bycatch is exceeding PBR. For seabird species for which a bycatch problem may be occurring, a review of any
new information should be conducted until either a seabird bycatch problem has been identified to exist or not to exist.
Where information remains uncertain regarding the existence of a bycatch problem, ICES recommends a precautionary
approach, including prioritizing monitoring efforts among other things, until sufficient information is collected to
determine whether or not a bycatch problem exists.
In the event of relevant new information becoming available, including for fisheries that are not believed to pose a risk at
present, the framework may be used to review and (re)categorize the risk.
ICES advises that sufficient information exists to identify fisheries where seabird bycatch is likely to be a problem (Table
1.5.1.3.1).
Information to parameterize PBR is available for many seabird species/populations. ICES recommends that in cases where
information is not available, suitable precautionary values are used, rather than investing heavily in improving e.g.
knowledge on population abundance. It would be valuable to develop guidance for the use of various recovery factors (f),
possibly by broad taxonomic groups or by status of population.
A further issue is that insufficient effort data are reported and/or available in many fisheries either known or expected to
have high bycatch levels. This applies particularly to smaller vessels; these can set relatively large quantities of static gear
that can pose risk to birds. An improvement in the spatial and temporal resolution of effort reporting would be needed to
avoid the risk of excessively precautionary advice.
Outside this recommended framework, ICES is aware that there may be other factors contributing to the identification of
a seabird bycatch problem. In particular, a nation may wish to undertake monitoring and/or mitigation measures based on
a less biologically-based approach, such as one of “societal choice” regarding indiscriminate removal of birds and/or
general wastefulness even where there may not be an immediate conservation risk. Any waste is unnecessary and waste
reduction should be encouraged.
3.
Data reporting format and database for seabird bycatch
ICES advises that seabird bycatch information be stored in the database on bycatch of marine mammals, birds, turtles,
and rare and/or endangered fish that is in a late stage of development within ICES. This ICES database was set up to
collate and review data from the National reports required under Council Regulation (EC) No. 812/2004. In parallel, a
standard reporting format was developed. While the standard reporting format was designed specifically for the tasks
under Council Regulation (EC) No. 812/2004, it was designed in such a way that it can contain bycatch data on other
groups than cetaceans. ICES advises the use of the standard reporting format defined for recording of marine mammal
bycatch under Council Regulation (EC) No. 812/2004.
The following adaptations are needed for reporting information on bycatch of seabirds:
1.
2.
3.
References to Council Regulation (EC) No. 812/2004 are redundant and should be removed.
In the section on acoustic deterrent devices, the two tables on acoustic deterrent devices are redundant. Any
mitigation should be described and referred to here.
In the section on observer schemes, the number of tables should be expanded to cover each of the gear types
monitored (i.e. “Longlines” should be added). The column with the unit of effort would need to be altered
depending on the gear monitored. The column “Days at Sea” should be retained in any additional table as this is
the most flexible and widely used unit of effort.
All EU Member States should report data in a standard electronic format to ensure easy import to the database. The ICES
database is in the process of being made web-accessible.
Sources
FAO. 2008. Report of the Expert Consultation on Best Practice Technical Guidelines for IPOA/NPOA–Seabirds, Bergen,
Norway, 2–5 September 2008. FAO Fisheries and Aquaculture Report, No. 880. FAO, Rome. 37 pp.
ICES. 2013. Report of the Workshop to Review and Advise on Seabird Bycatch (WKBYCS). ICES CM 2013/ACOM:61.
79 pp.
ICES Advice 2013, Book 1
47
1.5.2 EU DGENV
1.5.2.1
Special request, Advice June 2013
ECOREGION
General advice
SUBJECT
Request from EU for Scientific advice on data collection issues
Advice summary
Review of existing indicators
A summary of the qualities and the future utility of the existing Data Collection Framework (DCF) Annex XIII indicators
is provided. ICES advises that data collection and assessment to support indicators 5, 6, and 7 should continue. For
indicators 2, 3 and 4, ICES does not advise further implementation as there are challenges to target setting, and response
times are slow and variable. Indicators 1 and 8 have little further utility as they either do not address the priority issues in
the most effective way (indicator 1) or will shortly be superseded by legal or regulatory changes (indicator 8).
New indicators
In addition to development of existing DCF Annex XIII indicators 5, 6, and 7, ICES advises that new indicators are
required to track and to guide the management of the effects of fisheries on the ecosystem and so aid in the implementation
of the Marine Strategy Framework Directive (MSFD) through its descriptors. These indicators can be classified in the
following manner:
Removal 6 of protected and sensitive species (including bycatch of non-target species) (MSFD Descriptor 1)
An indicator of fishing effects on Endangered, Threatened and Protected (hereafter “protected”) and sensitive
species will be useful for the EU and its Member States to meet a number of policy and legislative targets.
Information is lacking on the abundance of, and bycatch of, many protected and sensitive species. Coverage of
fisheries under the DCF is biased away from those fisheries carrying the greatest risk of catching many protected
and sensitive species. Development of remote electronic video recording seems likely to be a cost-effective way
of assessing bycatch in the future as it can be applied to all parts of the fishing fleet (metiers and/or fleet
segments) as defined in DC-MAP (Data Collection – Multi-Annual Plan).
Foodweb effects (MSFD Descriptor 4)
Stock assessments of all forage fish species that account for >5% of the total fish biomass, or that are important
in the diet of dependent species (especially when these are protected species), are required. These assessments
should take account of the distribution and availability of the forage species to dependent predators. This
indicator will indicate whether sufficient prey are available for important predators in the foodweb. Among the
indicators that can describe changes in foodwebs, forage fish abundance and distribution is one of the few that
can respond in a defined way to a fishing activity and is relevant to Descriptor 4 of MSFD.
Impacts on seafloor habitats and associated communities (Damage to the seafloor and its biological
communities) (MSFD Descriptor 6)
ICES recommends some changes to the existing pressure indicators addressing this issue (DCF Annex XIII
indicators 5, 6, 7) to enhance their ability to assess impacts on seabed habitats. ICES advises that species
indicative of seabed habitat type caught in surveys, and by commercial vessels with on-board observers, be
recorded. As observers are already on some of these vessels, benthic data collection will be relatively costeffective. This will further provide links to MSFD criteria 6.1 and 6.2 (seafloor integrity) and 1.6 (biological
diversity). ICES recommends that fishing positions of all vessels, including those less than 12 m, be recorded
and reported at 30-minute intervals.
6
The word “removal” refers to extra mortality caused by fishing, including direct catch, bycatch and lethal interactions caused by collision
with fishing gear.
48
ICES Advice 2013, Book 1
Request
ICES is requested to assist in the identification of new data to be collected in support of the implementation of the Common
Fisheries Policy (CFP) and the Marine Strategy Framework Directive (MSFD).
ICES should also assist in the review of the existing environmental indicators to measure the effects of fisheries on the
marine ecosystem (2010/93/EU, Appendix XIII) [question 1] and in the selection and development of new indicators to
measure the impacts of fisheries on the marine ecosystem, including by-catch of non-target species, the food web and
damage to the seafloor and its biological communities, for each MSFD marine region or sub-region and finally make
proposals in time for the new DC-MAP 2014-2020 review [question 2].
ICES interpretation of the request is based on the understanding that it is from DG Environment and it is to explore the
overlap area between CFP and MSFD data needs – and not to describe all data needs for CFP and MSFD. Therefore,
some types of data that are not currently collected under the DCF but whose inclusion in the DC-MAP would be relevant
are not included in this response as they are considered to be solely related to the CFP.
Advice 7
Review of existing indicators (question 1)
ICES assessed the capacity of the DCF (2010/93/EU) Appendix XIII indicators 1 to 8 to detect and measure the effects
of fisheries on the marine ecosystem. Table 1.5.2.1.1 summarizes the future utility of each indicator.
ICES notes that the existing DCF Annex XIII indicators were intended to track fishing effects on the ecosystem, and that
targets cannot be set for all of these indicators. For this reason, ICES advises that if indicators are to be progressed to
support MSFD it is a condition that targets can be set to determine (a) when measures to achieve Good Environmental
Status (GES) have been established and (b) whether GES has subsequently been achieved.
New indicators (question 2)
ICES advises that two groups of indicators would be needed to measure the impacts of fisheries on the marine ecosystem:
(1) Pressure indicators that are suitable in describing the impacts of fisheries (i.e. metier and/or fleet segment) on the
marine ecosystem. It is important that data are collected and stored at the highest resolved metier and/or fleet segment
in DC-MAP.
(2) State and pressure indicators for which targets are set at the regional or sub-regional scale. The state indicators would
be used to describe the state of the ecosystem in relation to targets (e.g. targets consistent with achieving GES in the
MSFD). Corresponding pressure indicators would be used to define the levels of fishing pressure (e.g. as mortality
rates, spatial distribution of fishing activity) that would need to be achieved to meet the targets for state. Indicators
in this group would describe state in relation to targets for MSFD descriptors 1) biodiversity, 3) commercial fishes,
4) foodwebs, and 6) seafloor integrity, as these are directly affected by fishing.
7
In this advice, the use of ‘regions’ and ‘sub-regions’ is consistent with EC (2008).
ICES Advice 2013, Book 1
49
Table 1.5.2.1.1
50
Advice on existing environmental indicators to measure the effects of fisheries on the marine ecosystem, in relation to utility for implementing MSFD. Codes in
italics indicate potential relevance to MSFD descriptors and criteria.
Low – recommend discontinuation within DC-MAP.
Medium – keep for research but indicator not recommended for management purposes.
High – develop indicator further; DC-MAP should be developed to ensure that these indicators are calculated and reported.
Indicator
Definition
Future utility
1
Conservation status of
fish species
Indicator of biodiversity to be used for synthesizing, assessing, and
reporting trends in the biodiversity of vulnerable fish species.
Low; this indicator does not address pressure and state on the most sensitive species.
2
Proportion of large
fish (D1.3, D4.2)
Indicator for the proportion of large fish by weight in the assemblage,
reflecting the size structure and life history composition of the fish
community.
Medium; this indicator has a long response time to the effects of fishing and the
responses are variable. Although targets have been proposed they are not linked to a
clear consequence or benefit and may be perceived as having low policy relevance. Even
if a target is set, it cannot be used to guide management of specific metiers and/or fleet
segments.
3
Mean maximum
length of fishes
(D1.3)
Indicator for the life history composition of the fish community.
Medium; this indicator has a long response time to the effects of fishing and the
responses are variable. Although targets have been proposed they are not linked to a
clear consequence or benefit and may be perceived as having low policy relevance.
4
Size at maturation of
exploited fish species
(D1.3)
Indicator of the potential ‘genetic effects’ on a population.
Low; targets cannot be set, trends not linked to a clear consequence or benefit.
Management response to achieve targets not defined.
5
Distribution of fishing
activities (D6.1)
Indicator of the spatial extent of fishing activity. Reported in conjunction
with ‘Aggregation of fishing activities’.
6
Aggregation of
fishing activities
(D6.1)
Indicator of the extent to which fishing activity is aggregated. It would be
reported in conjunction with the indicator for ‘Distribution of fishing
activities’.
7
Areas not impacted by
mobile bottom gears
Indicator of the area of seabed that has not been impacted by mobile
bottom fishing gears in the last year, computed for a series of
bathymetric strata and potential substrate type. It responds to changes in
the distribution of bottom fishing activity resulting from catch controls,
effort controls, or technical measures (including MPAs established in
support of conservation legislation) and to the development of any other
human activities that displace fishing activity (e.g. wind farms).
High. Methods exist for analysis. Spatial footprints can be mapped by metier.
8
Discarding rates of
commercially
exploited species
(discarding can also
include unwanted
bycatch that is landed)
Indicator of the rate of discarding of commercially exploited species in
relation to landings.
Low; ICES notes that future policy will be to avoid all discards of commercial species;
there is thus no value in pursuing this indicator.
ICES Advice 2013, Book 1
Removal of protected and sensitive species (including bycatch of non-target species)
Knowledge of removal rate per unit effort, catch weight, or catch value will be required. To generate an indicator of the
consequences of removal of protected and sensitive species, it is necessary to know or assess the number of animals killed
in fisheries and the abundance of each species.
ICES advises that reliable schemes to establish population abundance of animals likely to be affected by fisheries removal
and the number of animals being caught should be established to measure population effects on protected and sensitive
species and to set targets for acceptable rates of removal.
ICES notes that it is a simple matter to generate a list of species protected under EU legislation. ICES suggests that a risk
assessment should be undertaken to focus DC-MAP data collection on those species most likely to be adversely affected
by fishing removal.
Foodweb effects
ICES advises that developing indicators of foodwebs is complex. While many indicators can describe changes, few
respond in a defined way to a manageable pressure. There is an exception to this advice; large ‘forage’ fish stocks which
provide important prey for other fishes, marine mammals, and seabirds. For these stocks, biomass and fishing mortality
should be assessed in relation to reference points. ICES advises that when stock assessments of forage fish include
estimates of natural mortality that incorporate top predators, the biomass limit reference points are then robust indicators
of the impact of fisheries on the provision of forage fish for the foodweb.
ICES notes that although most large populations of forage fish are currently assessed, some are not (for example sprats
and sandeels to the west of the United Kingdom) as they are presently not exploited. As a guideline, where there are
indications that these populations constitute more than ca.5% of the fish biomass in a region, data should be collected to
allow these populations to be brought into the assessment process. A process will be required to identify these stocks.
ICES advises that data be provided on the spatial structure of forage fish stocks and incorporated into stock assessments,
to allow biomass limit reference points to be set that prevent local depletions of forage fish by fisheries that would impact
on predators.
Impacts on seafloor habitats and associated communities (Damage to the seafloor and its biological communities)
ICES advises that the existing DCF Annex XIII indicators 5, 6, and 7 be extended to all metiers/fleet segments (this
includes smaller vessels that are currently not included in Vessel Monitoring System (VMS) regulations) and that more
frequent (30-minute) position updates be transmitted and recorded.
ICES notes that data on the distribution of main indicator species of benthic habitats and substrate (including. biogenic
habitats) could be identified to use in conjunction with the pressure indicators 5, 6, and 7. ICES advises that species
indicative of seabed habitat type caught in surveys, and on-board commercial vessels with on-board observers, be
recorded. This can be used to identify and prioritize for management gear/habitat interactions, and provide stronger links
to MSFD criteria 6.1 and 6.2 (seafloor integrity) and 1.6 (habitat condition).
Priorities for the collection of data on the ecosystem effects of fishing in DC-MAP
If collection of data to allow calculation of all the recommended indicators cannot be resourced, then the relative priorities
for the collection of data are:
1. Removal rates of protected species.
2. VMS data for all fleet segments and/or metiers.
3. Assessments of state of forage stocks.
4. Removal rates of sensitive species (defined following risk assessment).
5. Data on interactions between bottom fisheries and habitat.
Basis of the advice
Review of existing indicators
The review of existing indicators to measure the impacts of fisheries on the marine ecosystem was based on:
•
An analysis of existing DCF Annex XIII indicators made (see Table 1.5.2.1.2) considering whether:
ICES Advice 2013, Book 1
51
a.
b.
c.
d.
e.
•
the indicator has been tested or assessed,
a target can be set for the indicator,
the indicator is suitable for tracking fishing effects on the marine ecosystem,
there are challenges obtaining data used to calculate the indicator,
the indicator can be applied to all regions and sub-regions;
A review of the impacts of fisheries on the marine ecosystem that were not addressed by existing indicators but would
(a) indicate differences in the environmental impacts of fisheries and (b) indicate the extent to which fisheries
management measures influenced progress towards potential or stated targets.
Future assessment of DCF indicators
For the existing DCF Annex XIII indicators ICES will be calculating and reporting time-series for the existing indicators
this autumn (2013), recognising that four full years of data are now available for reporting. In conjunction with existing
ICES analyses and reports (ICES, 2012a, 2012b) this process will provide further insight into the performance of these
indicators and any constraints affecting their calculation and use. ICES will be making a data call in June 2013 to collate
the data required for this analysis.
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ICES Advice 2013, Book 1
Table 1.5.2.1.2
Review of existing DCF Annex XIII indicators. Codes in italics indicate potential relevance to MSFD descriptors and criteria.
Has indicator been
tested/assessed?
Can target be set?
Suitability for tracking fisheries
impact?
Challenges to data provision
Generic or region
specific
Conservation
status of fish
species
The indicator has been assessed
by ICES (2012a, 2012b), in EC
project reports (e.g. Borges et
al., 2011) and in scientific
literature (Dulvy et al., 2006).
Targets have been proposed
for purposes of investigating
performance of the indicator
but they are not explicitly
linked to existing legislation.
Captures trends in status of some fish
species but does not address well the
most sensitive species that are
potentially at highest risk from fishing
mortality (ICES 2012a, 2012b).
Can be calculated from trawl
survey data as collected to meet the
requirements of the current DCF.
Can be applied in
any region where
demersal trawl
surveys are
conducted.
Proportion of
large fish (D1.3,
D4.2)
The indicator has been
comprehensively assessed by
ICES (2012a, 2012b), EC
projects Piet et al. (2011),
Bloomfield et al. (2011),
Borges et al. (2011) and in the
scientific literature (e.g.
Shephard et al., 2011;
Greenstreet et al., 2011)
Targets have been proposed
but they are not explicitly
linked to existing legislation
or linked to a clear
consequence or benefit.
Captures trends in response of fish
community to fishing. Principal
concerns are slow and variable
responses to changes in management,
and technical issues with methods
(ICES 2012a, 2012b).
Can be calculated from trawl
survey data as collected to meet the
requirements of the current DCF.
Can be applied in
any region where
demersal trawl
surveys are
conducted.
The indicator has been assessed
by ICES (2012a, 2012b) and in
EC projects Piet et al. (2011),
Bloomfield et al. (2011), and
Borges et al. (2011).
Targets have been proposed
but they are not explicitly
linked to existing legislation
or linked to a clear
consequence or benefit.
Captures trends in response of fish
community to fishing. Principal
concerns are slow and variable
responses to changes in management
and technical issues with methods
(ICES 2012a, 2012b).
Can be calculated from trawl
survey data as collected to meet the
requirements of the current DCF.
Can be applied in
any region where
demersal trawl
surveys are
conducted.
Size at
maturation of
exploited fish
species (D1.3)
The indicator has been assessed
by ICES (2012b). There is
scientific uncertainty over
whether genetic change is
induced by fishing (e.g.,
Hutchings and Fraser (2008),
Kuparinen and Merilä (2007)).
Targets have not been
proposed, indicator
recommended to track trends
in size at maturation.
Unknown: performance not
comprehensively assessed.
Data to calculate this indicator are
collected on the current DCF but
for relatively few species (ICES,
2012b).
Can be applied in
any region where
size at maturity is
estimated.
Distribution of
fishing activities
(D6.1)
Further developed into two
specific and operational
indicators: (a) Total area fished
and (b) Proportion of surface
area fished. The indicator has
been assessed by ICES
(2012b).
At present no target value
exists.
Only suitable for tracking fishing
impact in relation to D6 if based on
fishing metiers that actually disturb the
seafloor. In that case (b) is the
preferred indicator as this shows the
proportion of the seafloor disturbed
annually.
Confidentiality issues often prevent
access to VMS data in a format to
calculate the indicators at the
appropriate spatial and temporal
scale. Not all fisheries have VMS.
This indicator can
be calculated for
any area. They can
even be calculated
for a specific habitat
(potential relevance
for D1) if data exist.
Indicator
1
2
3
4
Mean maximum
length of fishes
(D1.3)
5
ICES Advice 2013, Book 1
53
Indicator
Aggregation of
fishing activities
(D6.1)
6
Areas not
impacted by
mobile bottom
gears
7
8
54
Discarding rates
of commercially
exploited
species
(discarding can
also include
unwanted
bycatch that is
landed)
Has indicator been
tested/assessed?
Further developed into two
specific and operational
indicators, i.e. (a) Proportion of
surface area fished by specific
proportion of effort, and (b)
Proportion of surface area
fished at specific intensity.
Indicator has been assessed by
ICES (2012b).
Further developed into two
specific and operational
indicators, i.e. (a) Cumulative
proportion of surface area not
impacted over a specific time
period, and (b) Proportion of
surface area not impacted at
specific level of confidence.
Indicator has been assessed by
ICES (2012b).
Not tested systematically
though discard rates are used in
some parts of ICES advice.
Can target be set?
At present no target value
exists.
Suitability for tracking fisheries
impact?
Only suitable for tracking fishing
impact in relation to D6 if based on
fishing metiers that actually disturb the
seafloor. In that case (b) is the
preferred indicator, showing the
proportion of the seafloor fished more
than once a year.
Generic or region
specific
Challenges to data provision
Confidentiality issues often prevent
access to VMS data in a format to
calculate the indicators at the
appropriate spatial and temporal
scale.
Not all fisheries have VMS.
This indicator can
be calculated for
any area. It can even
be calculated for a
specific habitat
(potential relevance
for D1) if data exist.
At present no target value
exists.
This indicator was intended to show
the impact on the seafloor and is
therefore the most suitable. In this case
(a) is the preferred indicator showing,
the proportion of the seafloor not
impacted over a period long enough to
assume it is recovered even if disturbed
prior to this period. As such this
proportion is by definition in Good
Environmental Status (GES) if not
impacted by other human activities.
Confidentiality issues often prevent
access to VMS data in a format to
calculate the indicators at the
appropriate spatial and temporal
scale. Not all fisheries have VMS.
The absence of VMS coverage for
vessels under 12 m is of particular
importance in inshore and coastal
areas.
For potential relevance to D1
benthic bycatch and substrate
should be reported.
This indicator can
be calculated for
any specific area. It
can even be
calculated for a
specific habitat
(potential relevance
for D1) if data exist.
At present no target value
exists
This tracks additional mortality on
commercial fish stocks, and is
necessary to understand total pressure
on a stock
No major challenges to data
provision but relies on unbiased
sampling of fisheries.
This indicator can
be calculated for
any specific area.
ICES Advice 2013, Book 1
New indicators
ICES advises that three new classes of indicators should be supported by DC-MAP. These are: ‘removal of protected and
sensitive species’, ‘foodweb effects’, and ‘impact on seafloor habitats and associated communities’. Table 1.5.2.1.3
summarizes the new proposals for indicators. These new indicators are general rather than technical specifications of the
indicator. ICES recommends that when/if indicators are carried forward, detailed specifications must be prepared and
analytical methods supported by common analytical tools.
Table 1.5.2.1.3
Issue
Removal
rates of
protected
and sensitive
species
Foodweb
effects
Impacts on
seafloor
habitats and
associated
communities
Proposed indicators to address the three issues identified in the advice, the relevance of these
indicators to the MSFD and their use (comparing state and pressure in relation to reference points).
MSFD
relevance
D1(D4)
D4.3
D6.1
Indicator(s)
Frequency
Usage
Removal rates of protected species in
relation to population size by region
and sub-region.
Removal rates of sensitive species in
relation to population size by region
and sub-region.
Fishing mortality rate on forage fish
stocks expressed in relation to reference
points.
Spawning-stock biomass of forage fish
stocks expressed in relation to reference
points.
Spatial distribution of forage fish stocks
expressed in relation to reference
points.
Distribution of fishing activities (based
on DCF Annex XIII indicator 5) by
fleet segment/metiers, expressed in
relation to fisheries effort, catch rate,
and catch value.
Aggregation of fishing activities (based
on DCF Annex XIII indicator 6) by
fleet segment/metiers, expressed in
relation to fisheries effort, catch rate,
and catch value.
Areas not impacted by mobile bottom
gears (based on DCF Annex XIII
indicator 7) by fleet segment/metiers at
small scales and for combined fleets at
regional and sub-regional gears.
Calculated
annually.
Calculated
annually.
Comparison of removal rates of
protected species with reference
points.
Comparison of removal rates of
sensitive species with reference
points.
Comparison of mortality on forage
fish stocks with reference points.
Calculated
annually.
Comparison of status of forage fish
stocks with reference points.
Calculated
annually.
Comparison of distribution of forage
fish stocks with reference points.
Calculated
annually.
Comparison of relative effects of
different fleet segments/metiers on
seabed habitats. No reference point.
Calculated
annually.
Comparison of relative effects of
different fleet segments/metiers on
seabed habitats. No reference point.
Calculated
annually.
Assessment of extent of areas
unimpacted by towed bottom gears.
No reference point.
Calculated
annually.
Use of DC-MAP data and indicators to support MSFD
The MSFD provides a clear context for indicator development because the CFP is required to be used as the primary
instrument to manage the impacts of fisheries on the marine ecosystem to the extent necessary to achieve GES.
For the DC-MAP, ICES considers that the priority in relation to this request is to provide the data needed to report
indicators for impacts of fisheries on the marine ecosystem that pose the greatest risk and are most likely to be
unsustainable.
ICES assumes that DC-MAP will be implemented through the EU Member States at a sub-regional, fishery, or fleet level,
whereas the MSFD targets are the responsibility of the EU Member States alone. Whilst the EU Member States are
encouraged to work together to define MSFD sub-regional targets, the setting of targets could be done in isolation from
other regional EU Member States. This contrasts with the expected approach in DC-MAP. ICES notes that indicators to
measure the impacts of fisheries on the marine ecosystem that are based on data collected in DC-MAP are most valuable
if there is sufficient consistency in the implementation of MSFD among EU Member States, ensuring that all EU Member
States in a given region or sub-region can use DC-MAP data and associated indicators. Alternatively, DC-MAP indicators
would need to be developed to take account of the intentions of EU Member States in a given region or sub-region. ICES
notes that surveys supported by DC-MAP also provide EU Member States with the opportunity to use the surveys as
platforms of opportunity, collecting data that describe the impacts of fishing on marine ecosystems that may be relevant
nationally.
ICES Advice 2012, Book 1
55
Removal of protected and sensitive species (including bycatch of non-target species)
Many species are caught that are not targeted. The indicators for fish will include some non-target species, but the main
species of fish that may be adversely affected by bycatch are large species with low reproductive rates such as sharks and
rays. Species that are included in the formal ICES fish stock assessment process need not be included in this group of
indicators, but all others should be. Other non-target species that are affected include mammals, seabirds, and turtles. The
bycatch of mammals and turtles should be monitored under the EU Habitats Directive (92/43/EEC); bycatch of cetaceans
is also covered by Council (EC) Regulation No. 812/2004. In 2012 the Commission adopted an Action Plan to reduce
incidental catches of seabirds in fishing gears; this plan includes requirements for data collection. An equivalent Action
Plan for sharks was adopted in 2009.
At present, the bycatch of some species is reported by observers, working under DCF, on-board vessels. The forthcoming
‘discards ban’ may affect future monitoring and data collection. It could, for example, result in much greater emphasis on
port-based sampling schemes, rather than sea-going observer schemes. It seems likely that bycatch of protected species
will continue to be returned to the sea as they are “non-commercial” and unlicensed possession of some of these species
(especially cetaceans) is illegal in most EU Member States.
The proposed indicator is the removal rate of all species protected by legislation and of all sensitive species. Removal
rates would be reported as numbers and sizes of individuals caught and expressed in relation to fishing effort and/or catch
weight and/or catch value in the metier and/or fleet segment. To identify the species that will be monitored in all regions
and sub-regions a list of these species should be compiled for each region and sub-region. ICES recommends the
application of a risk assessment process (e.g. as reviewed by ICES, 2012b) that considers the sensitivity of the species (to
removal) in the first instance, followed by an assessment, if possible, of its exposure to fishing. The process should
consider all fishing operations in all regions, stratified by the most highly resolved level of fleet classification used to
collect data for fisheries management in DC-MAP.
In conjunction with information on the population size of protected and sensitive species, the removal rates could be used
to assess impacts on the populations in relation to reference points. Limit removal rates for some species have been agreed
in some political settings (e.g. for harbour porpoise by the regional conservation agreement for small cetaceans,
ASCOBANS), and could potentially be set, for other populations, and the values of indicators in relation to targets can
be used to report on progress towards meeting existing commitments and adopt appropriate measures to achieve GES for
MSFD Descriptor Criterion 1.3.
Collection of reliable information on removal rates of sensitive and protected species is most commonly undertaken by
on-board human observers. Sampling under the current Data Collection Framework (DCF) tends to focus on the metiers
that discard the most fish; these are not necessarily the same metiers that have the largest catch of species of interest.
Thus, bottom trawling is generally well sampled, while in some specific fishing areas set nets, longlines, and purse-seines
are undersampled. Some EU Member States have undertaken additional observation schemes to meet the requirements
of Council Regulation No. 812/2004 and those of the Habitats Directive (92/43/EEC). It would be possible to better define
requirements on EU Member States under the DCF, but much will depend on how other data collection requirements will
change under the revised Common Fisheries Policy (CFP).
Alternatives to monitoring by human observers on-board vessels could include remote electronic video recording and
monitoring from vessels visiting a fishing fleet. Of these alternatives remote electronic video recording seems to have the
greatest potential to meet many of the needs of the existing DCF and also to improve monitoring of bycatch of noncommercial species, and has the advantage of being useable on metiers and/or fleet segments where the carriage of a
human observer poses logistical problems.
Foodweb effects
ICES considers that when stock assessments of forage fish include estimates of natural mortality that incorporate top
predators, the biomass limit reference points from the MSY approach are then robust indicators of the impact of fisheries
on the provision of forage fish for the foodweb. When a stock assessment does not incorporate realistic estimates of
predator-induced mortality, then MSY limit reference points may not be appropriate, and some alternative mechanism for
ensuring forage fish biomass for predators may need to be found. Some large populations of forage fish are not assessed,
primarily because they are not exploited to any great extent. In this situation, assessments of the populations should be
carried out if the populations are thought to be of a significant size (>5% of the total fish biomass) based on catches, bird
food needs, acoustic surveys, ichythoplankton surveys, and other analytical methods. The choice of 5% is arbitrary and
offered as provisional guidance.
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ICES Advice 2013, Book 1
Impacts on seafloor habitats and associated communities (Damage to the seafloor and its biological communities)
VMS data are currently collected for assessing compliance with the CFP as detailed in the ‘Control Regulation’ (EC,
2009). In this advice, modifications to VMS collection procedures and greater VMS data exchange are proposed to
improve the existing DCF Annex XIII indicators and to support interpretation of new state indicators. ICES recognises
that changes in the collection of VMS data may not be affected through DC-MAP, but considers that indicators based on
VMS data will be necessary to assess the effects of fishing on marine ecosystems in support of the MSFD and other
legislation.
Calculation of the VMS indicators will require that VMS data for all metiers and/or fleet segments included in DC-MAP
are available from EU Member States. To facilitate exchange and allow calculation of the indicators for all metiers, ICES
recommends that data are shared by EU Member States, using gridded data that record the number of VMS fishing records
by month and metier and/or fleet segment. ICES recognises that grids can introduce some small biases when indicators
are calculated with VMS data allocated to fixed grids (e.g. Piet and Hintzen, 2010; Gerritsen et al., 2013), but the exchange
of data will rely on providing individual vessels with sufficient anonymity to support full international exchange of all
VMS data. ICES recommends the sharing of gridded point data at 0.05 resolution, as already trialled in EC projects
(Bloomfield et al., 2011). Metiers and/or fleet segments to which position records are allocated should be determined by
the fisheries management requirements of the DC-MAP. ICES recommends that the fishing positions of all vessels are
recorded and reported at 30-minute intervals.
The indicators are calculated for all metiers and/or fleet segments fishing with towed bottom gears, but VMS coverage
will be required for all other vessels to track their interactions with the environment. ICES recommends that this should
include all fishing vessels in all waters in regions and sub-regions, including smaller and inshore vessels not currently
monitored with VMS.
Recording benthic bycatch and substrate (including biogenic habitats) will enhance the interpretation of these indicators.
They can then be used to identify and prioritize for management gear/habitat interactions and extend the value of these
pressure indicators to provide direct links to MSFD criteria 6.1 and 6.2 (seafloor integrity) and 1.6 (habitat condition)
(ICES, 2012a).
Sources
Bloomfield, H., Nolan, C., Le Quesne, W. J. F., Raakjær, J., Christensen, A. S., Aanesen, M., Armstrong, C., Piet, G. J.,
and Frid, C. 2011. Fisheries Ecosystem Plan: North Western Waters. Making the European Fisheries Ecosystem
Plan Operation (MEFEPO): Work Package 7 Report.
Borges, M. F., Mendes, H., Bloomfield, H. J., Raakaer, J., Pinho, M. R., Duchêne, J., Porteiro, C., Velasco, F., Hilly, C.,
Aanesen, A., Armstrong, C., Piet, G. J., and Frid, C. L. J 2011. Fisheries Ecosystem Plan: South Western Waters.
Making the European Fisheries Ecosystem Plan Operational (MEFEPO): Work Package 7 Report.
Dulvy, N. K., Jennings, S., Rogers, S. I., and Maxwell, D. L. 2006. Threat and decline in fishes: an indicator of marine
biodiversity. Canadian Journal of Fisheries and Aquatic Science, 63:1267–1275.
EC. 2008. Directive 2008/56/EC of the European Parliament and of the Council of 17 June 2008 establishing a framework
for community action in the field of marine environmental policy (Marine Strategy Framework Directive). Official
Journal of the European Union, L164: 19–40.
EC. 2009. Council Regulation (EC) No. 1224/ 2009 of 20 November 2009 establishing a Community control system for
ensuring compliance with the rules of the Common Fisheries Policy, amending Regulations (EC) No. 847/96, (EC)
No 2371/2002, (EC) No. 811/2004, (EC) No. 768/2005, (EC) No. 2115/2005, (EC) No. 2166/2005, (EC) No.
388/2006, (EC) No. 509/2007, (EC) No. 676/2007, (EC) No. 1098/2007, (EC) No. 1300/2008, (EC) No. 1342/2008
and repealing Regulations (EEC) No. 2847/93, (EC) No. 1627/94 and (EC) No.1966/2006. Official Journal of the
European Union, L343: 1–50.
EC. 2010. Commission decision of 1 September 2010 on criteria and methodological standards on good environmental
status of marine waters. Official Journal of the European Union, L232: 14–24.
Gerritsen, H. D., Minto, C., and Lordan, C. 2013. How much of the seabed is impacted by mobile fishing gear? Absolute
estimates from Vessel Monitoring System (VMS) point data. ICES Journal of Marine Science, 70: 523–531.
Greenstreet, S. P. R., Rogers, S. I., Rice, J. C., Piet, G. J., Guirey, E. J., Fraser, H. M., and Fryer, R. J. 2011. Development
of the EcoQO for the North Sea fish community. ICES Journal of Marine Science, 68:1–11.
Hutchings, J. A., and Fraser, D. J. 2008. The nature of fisheries- and farming-induced evolution. Molecular Ecology, 17:
294–313.
ICES. 2012a. Marine Strategy Framework Directive – Descriptor 3+. ICES CM 2012/ACOM:62.
ICES. 2012b. Report of the Working Group on the Ecosystem Effects of Fishing Activities (WGECO). ICES CM
2012/ACOM:26.
ICES Advice 2012, Book 1
57
Kuparinen, A., and Merilä, J. 2007. Detecting and managing fisheries-induced evolution. Trends in Ecology and
Evolution, 22: 652–659.
Piet, G. J., Bloomfield, H. J., Rockmann, C., Miller, D., van Hal, R., Raakjær, J., Christensen, A. S., Aanesen, M.,
Armstrong, C., and Frid, C. L. J. 2011. Fisheries Ecosystem Plan: North Sea. Making the European Fisheries
Ecosystem Plan Operation (MEFEPO): Work Package 7 Report.
Piet, G. J., and Hintzen, N. T. 2012. Indicators of fishing pressure and seafloor integrity. ICES Journal of Marine Science,
69: 1850–1858.
Shephard, S, Reid, D. G., and Greenstreet, S. P. R. 2011. Interpreting the large fish indicator for the Celtic Sea. ICES
Journal of Marine Science, 68: 1963–1972.
58
ICES Advice 2013, Book 1
1.5.2.2
Special request, Advice November 2013
ECOREGION
SUBJECT
General advice
Request from EU for scientific advice on data collection issues – part 2
Advice summary
ICES provides an inventory (in the form of annexed tables) of the main bycatch issues for fisheries in each of Europe’s
Data Collection Framework (DCF) regions (Baltic, Atlantic, Mediterranean, Black Sea). An assessment is made as to
how well the current DCF meets the need to understand these fishery interactions in the context of the EU’s Marine
Strategy Framework Directive (MSFD).
The detailed design of catch and bycatch observation schemes should integrate the needs for data both for fish stock
assessment and for ecosystem assessment purposes. ICES advises that detailed planning, dependent on decisions at policy
level, will be required to integrate all these data collection needs into existing survey protocols while ensuring that existing
monitoring commitments are not compromised.
The design of on-board observer schemes, whether carried out by humans or by remote technology (e.g. closed-circuit
television CCTV) will also need care, and will need to take account of likely future changes in human observer coverage
as a consequence of the ‘landings obligation’ being introduced.
Detailed data on fishing effort will be required for any assessment of the effect of fishing. Data requirements are of higher
temporal and spatial resolution and differ from those currently used for fish stock assessments.
Further research and additional survey effort (including additional surveys) will be needed to interpret several of the DCF
and MSFD indicators, especially if they are to be used in management.
Request
According to the MoU between ICES and the European Commission, ICES shall provide further scientific advice on data
collection issues. ICES is therefore requested to assist in the identification of new data to be collected in support of the
implementation of the Common Fisheries Policy (CFP) and the Marine Strategy Framework Directive.
Indicators for impacts on the ecosystem from fisheries can contribute to assessments for MSFD Descriptors 1, 4 and 6.
As such they would need to be integrated with assessments of non-fishery impacts in order to provide an overall
assessment for these descriptors in each (sub-) region. This will require discussion with Member States (via the Regional
Sea Conventions) on how to incorporate such indicators. ICES should provide recommendations on how this can be
included in the MSFD assessment and reporting process, as well as the implementation of the EU Biodiversity Strategy,
including the periodic assessment of the data and access to the data and assessments.
ICES interpretation of this request is based on the understanding that the DG Environment wants to consider how further
data could be collected via the DCF/DC-MAP that would also be useful in the implementation of the MSFD and the EU
Biodiversity Strategy. The European Commission clarified the request by suggesting a simplified scope to address the
request in a logical sequence:
(a)
(b)
(c)
Produce an inventory of the main fisheries per region:
Identify the main bycatch issues per fishery (initially whether it is birds, mammals, reptiles, noncommercial fish or benthos);
Coarsely quantify which fisheries are the main threats to each of these groups – some sort of high-level
prioritisation; i.e. bird bycatch is an important issue for fishery X and Y in region Z).
Assess how well current DCF addresses the main threats – to indicate where current DCF is OK and
hence priorities for revision.
Consider what methods for data collection (e.g. observers, use of CCTV etc.), sampling regime and
periodicity would lead to the collection of data suitable for an indicator (Note there may be several
options and costs might vary considerably, depending on links to observer systems for commercial
stocks etc.) – it may be too early to pin down precisely the best methods.
ICES provided advice on other parts of the request from DG ENV (not quoted above) earlier in 2013:
http://www.ices.dk/sites/pub/Publication%20Reports/Advice/2013/Special%20requests/EU_%20data_%20collection_is
sues.pdf.
ICES Advice 2012, Book 1
59
ICES advice
Inventory of main fisheries and their bycatch
Summary overviews of the main fisheries (metiér level 4) for each of the Data Collection Framework regions and their
potential for bycatch have been made for the vertebrate groups birds, mammals, reptiles, elasmobranchs, and bony fish
(Annex 1). The first three of these groups include all species that occur in the respective region, while the overviews for
fish are based on the threatened and declining fish species listed by HELCOM, OSPAR, and the Barcelona Convention.
Roughly half of the listed species are sampled for biological variables in commercial fisheries under the DCF. Most
elasmobranch species are sampled.
Non-target and non-commercial fish are taken as bycatch in many fisheries, notably by trawls, nets, and seines. This
includes many sharks and rays among elasmobranchs, and also many species of bony fish. Species of marine mammals
are taken as bycatch in some fisheries, including by pelagic trawls and nets, as well as in longline fisheries in the
Mediterranean Sea. Seabirds are taken in some fisheries, notably in nets and longline fisheries. Reptiles are taken as
bycatch in net and trawl fisheries in the Mediterranean Sea.
Summary overviews of the potential to physically impact benthic habitats are provided for the same fisheries (Annex 2).
Habitats chosen for this evaluation are relevant to each DCF region. The degree to which each habitat is affected by
bottom gears depends on the scale of the fishing operations and the sensitivity of the habitat. Bottom trawls generally
affect the largest areas and have the potential to cause most damage to sensitive habitats. Pelagic trawls on the other hand
do not generally come in contact with the seafloor and have no impacts. Set nets, longlines, seines, and traps have more
spatially limited contact with the seafloor and generally smaller and more local effects compared to bottom trawls. There
is limited information on the potential impacts from some gears on benthic habitats, as reflected by question marks in the
tables.
It should be noted that these overview assessments represent a wide span in real or potential impacts or threats, from low
levels that might be assessed as insignificant, up to substantial and serious threats. Some impacts may be local while
others will be widespread. If these assessments are to be used in management or targeting of studies/research, it will be
necessary to carry out more detailed assessments in order to scale the impacts or threats for the various combinations of
fishing activities and species or habitats. Because of this, ICES is not able to directly quantify all impacts.
Current DCF sampling in relation to main threats
There are gaps in the bycatch data for marine mammals, seabirds, reptiles, and of species indicative of benthic habitats,
because there is no obligation in the current DCF to record this information. The gaps identified for monitoring the status
of threatened and declining fish species are for coastal and inshore (some anadromous) listed species, pelagic sharks, and
demersal deep-water species south of ICES Subarea VI.
There is currently a gap in information on the spatial distribution of fishing activities by vessels under 12 m (in some
regions, for example the Mediterranean, VMS data from fishing vessels of less than 15 m in length are not available).
Data collection methods and recommendations
The DCF requires a sampling programme of commercial fisheries that includes landings on shore and total catches
(including discards) at sea. Sampling effort is stratified according to the relative contribution of a particular metiér to
overall landings, value of landings, and fishing effort. As a consequence, this sampling effort may not be adequate to
provide sufficient data on fisheries that have a particularly high bycatch of certain protected, threatened, or declining
species.
The detailed design of catch and bycatch observation schemes should integrate the needs for data both for fish stock
assessment and for ecosystem assessment purposes. Monitoring should be based on statistically sound sampling schemes
and will need a number of inputs, including a detailed set of quality targets and some knowledge of the required precision
for indicators. Guidance on the desired precision, development, and provision of quality metrics of collected data would
make it possible to advise on sampling intensity and the stratification of sampling. Guidance on prioritizing differing
needs for time and personnel resources will also be needed. These are societal, not scientific, judgements that require the
input of policy-makers.
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ICES Advice 2013, Book 1
There are several general principles to follow when establishing an observer scheme (regardless of method of
observation).
•
•
•
•
Vessels with gears that apparently cause most unwanted bycatch should have highest sampling, based on a riskbased approach.
If possible, vessels should be selected randomly (ideally working with the industry, perhaps through fishing
federations).
Relevant parameters of the fishing operation should be collected, such as technical features of the fishing gear,
location, frequency of the fishing activities, etc.
Power analyses can be used to estimate and stratify studies; it may not be necessary to observe every ship every
year to estimate the amount of bycatch per gear.
Additional information on the state of threatened and/or declining species and habitats is needed. The use of existing
monitoring programmes may not be sufficient to get adequate information on many species and habitats. Recording the
(by-)catch of these species by observers or scientific surveys might fill an information gap, as long as it is a limited list
of readily recognisable species (including epifauna as indicators for their associated threatened and declining habitats)
that can provide valuable information on, e.g. distribution of these species and habitats.
The use of observation schemes on commercial vessels may not be sufficient to determine the state or condition of benthic
species and habitats. This is due to the variation in catchability between benthic species, and our lack of detailed
knowledge of this variation. A better assessment may be made based on models linking data on the location of fishing
activities and their effects on benthic habitats. However, if an observer is on board and benthic species are bycaught,
photos can be made for determination. This information could also be used to improve the quality of modelling.
Increasing the scope of observer programmes and of CCTV observations of bycatch and discards need to be considered
under the perspective likely decisions of the EU to introduce landing obligations. Assuming that there is compliance with
the landing obligation, it is likely that observations of catch (and commercial species bycatch) could switch from being
predominantly at sea to being predominantly on land due to cost–benefit reasons. This would reduce the potential for atsea observations of other features such as bycatch by human observers.
When using CCTV cameras on board vessels, the following issues will need to be addressed.
•
•
•
•
A catch (and bycatch) sampling scheme will still be required to confirm some information (e.g. species identity,
age).
Compulsory CCTV schemes, and schemes that recompense or incentivize fishers are more likely to be successful
than voluntary schemes.
Protocols for the analysis of CCTV records will need to be developed.
Additional requirements for recording in logbooks (e.g. for rare species, species listed under the Habitats and
Birds Directives, or under the Regional Sea Conventions) could be required when CCTV is in use, in order to
compensate for the loss of records from on-board observers. The association of position (from integration of
electronic logbook to GPS) could provide spatial details on the area where species were caught. The technical
feasibility of such an approach might be experimentally tested on portions of the fleets.
Species known to be indicative of seabed habitat type, caught in surveys and on-board commercial vessels with on-board
observers, should be recorded. This information can be used to identify and prioritize the management of gear/habitat
interactions and to provide stronger links to implementation by EU Member States working through the Regional Sea
Commissions of MSFD criteria 6.1 and 6.2 (seafloor integrity) and 1.6 (habitat condition). The inclusion of benthic taxa
to be assessed by on-board observation may need the development of guidelines and the availability of proper taxonomic
expertise.
Assessing the surface and sub-surface disturbance by bottom contact gears for the proposed MSFD indicators (of
HELCOM and OSPAR) requires data on the extent of physical damage and loss of seabed habitats resulting from human
activities. Fishing activity information therefore needs to be provided on the spatial distribution of fishing, including:
location (maximum 30-minute position updates, preferably shorter), gear type (Levels 4 and5), gear width, vessel speed,
and whether fishing is occurring or not. Effort should be recorded in appropriate units (e.g. hours towed, km of net × soak
time, number of hooks set).
ICES Advice 2012, Book 1
61
To better interpret the results from monitoring under DCF, ICES offers the following further advice.
a)
Additional research is required to better understand the ‘fishing pressure – benthic state’ relationship and to
develop predictive tools for this means.
b) The spatial distribution of most habitat features is generally only known at a coarse scale. If impacts are to be
assessed at a finer scale, further research and survey will be required (in some cases modelling may be adequate).
c) Equally, knowledge of the population abundance and the spatial and temporal distribution of many species is
inadequate. Dedicated surveys are likely to be required to remedy this situation.
d) If indicators are to be used to inform management, then it will be important to distinguish between effects caused
by human activities and those that may be described as natural (e.g. hydrographic change). This may require data
collection beyond that needed to assess the state of the indicators.
Annually collected DCF data and Regional Seas indicators on fisheries impacts could contribute to the overall assessment
and reporting for D1, 4, and 6 of the MSFD.
Integrated assessment
Data collected under DCF in the period 2014–2020 can be used to (further) develop, test, and evaluate the Regional Seas
indicators. Information from adopted indicators can be included in the reporting process of the Regional Sea Commissions
and included in Regional Sea Commission Assessments, leading to a common report for each (sub)region of the MSFD
assessment. This will support Member States in reporting for the assessment required in 2018 under the MSFD.
Furthermore, the interim data of DCF may be used for future state of the environment of the Regional Sea Commissions
(such as the OSPAR Quality Status Report in 2021 and future HELCOM reports on the Ecosystem Health of the Baltic
Sea).
Integrated assessment (IA, or integrated ecosystem assessment, IEA) is seen as a core element of the ecosystem approach
to management, being the step where information from monitoring is compiled and evaluated as a basis for scientific
advice on management measures. ICES advises that IA should be used as a mechanism for integrating information
collected for the various purposes under the CFP and MSFD, including indicators for impact of fisheries on other
components of the ecosystem than commercial fish. ICES has established working groups for integrated assessment for
some of the MSFD regions, including the Baltic Sea and the North Sea. These working groups can contribute to the
overall holistic assessments of the status and trends of the regional ecosystems supporting the reporting by EU member
states according to MSFD (and other) requirements.
Sources
Anderson, O. R. J., Small, C. J., Croxall, J. P., Dunn, E. K., Sullivan, B. J., Yates, O., and Black, A. 2011. Global seabird
bycatch in longline fisheries. Endangered Species Research, 14: 91–106.
Bazairi, H., Ben Haj, S., Boero, F., Cebrian, D., De Juan, S., Limam, A., Lleonart, J., Torchia, G., and Rais, C. (Eds.)
2010. The Mediterranean Sea Biodiversity: state of the ecosystems, pressures, impacts and future priorities. UNEPMAP RAC/SPA, Tunis. 100 pp.
Casale, P. 2011. Sea turtle by-catch in the Mediterranean. Fish and Fisheries, 12: 299–316.
Cebrian Menchero, D. 2010. Mitigation measures needed for reducing by-catch of seabirds in the Mediterranean region.
General Fisheries Commission for the Mediterranean. Meetings of the GFCM Subsidiary Committees. SCMEE. 21st
November–3rd December 2010.
Cosgrove, R., and Browne, D. 2007. Cetacean by-catch rates in Irish gillnet fisheries in the Celtic Sea. Bord Iascaigh
Mhara. Marine Technical Report, June 2007.
GFCM. 2008. Report of the meeting of the ByCBAMS projecT (jointly between ACCOBAMS and SCMEE). Rome,
Italy, 17–18 September 2008. General Fishery Commission for the Mediterranean. Scientific Advisory Committee.
ICES. 2013a. Report of the Working Group on Bycatch of Protected Species (WGBYC), 4–8 February 2013, Copenhagen,
Denmark. ICES CM 2013/ACOM:27. 73 pp.
ICES. 2013b. Report of the Workshop on Data Collection – Assessments of non-fishery impacts (WKDCF-NF), 8–10
October 2013, Copenhagen, Denmark. ICES CM 2013/ACOM:74. 65 pp.
OSPAR. 2010. Quality Status Report 2010. OSPAR Commission, London.
Tudela, S. 2004. Ecosystem effect of fishing in the Mediterranean. General Fisheries Commission for the Mediterranean.
Studies and Reviews, N74. 44 pp.
Zydelis, R., Small, C., and French, G. 2013. The incidental catch of seabirds in gillnet fisheries: A global review.
Biological Conservation, 162: 76–88.
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ICES Advice 2013, Book 1
Annex 1
Potential bycatch of vertebrate groups in fishing metiérs for the four DCF
regions
NA (not applicable) – the vertebrate group does not occur; N (no) – the fishing metiér does not impact the vertebrate
group (or bycatch is minimal); Y (yes) – a real or potential impact on the vertebrate group; ? – the fishing metiér and
vertebrate group are likely to overlap in space and time but with insufficient information to make a judgement. Colours
of fishing gear cells symbolize level of activity: orange – common fishing gear/activity in this ecoregion; green –
negligible or non-existent; white – not known.
Table 1.5.2.2.1
Baltic region (based on Anderson et al., 2011; Cosgrove and Browne, 2007; ICES, 2013a; Zydelis et al., 2013).
Threatened and declining
Gear groups
Bottom trawls
Gear type
Birds
Mammals
Reptiles
Elasmobranch
Bony fish
Bottom otter trawl [OTB]
Y
Y
NA
Y
Y
Multi-rig otter trawl [OTT]
?
?
NA
Y
Y
Bottom pair trawl [PTB]
?
?
NA
Y
Y
Midwater otter trawl
[OTM]
?
Y
NA
N
Y
Midwater pair trawl [PTM]
?
Y
NA
N
Y
Rods and Lines
Hand and Pole lines [LHP]
[LHM]
N
N
NA
Y
N
Longlines
Drifting longlines [LLD]
?
N
NA
?
N
Set longlines [LLS]
?
N
NA
?
N
Pots and Traps [FPO]
N
Y
NA
N
N
Fykenets [FYK]
N
Y
NA
N
N
Stationary uncovered
poundnets [FPN]
N
Y
NA
N
N
Trammelnet [GTR]
Y
Y
NA
Y
Y
Set gillnet [GNS]
Y
Y
NA
Y
Y
Surrounding nets
Purse-seine [PS]
?
N
NA
?
Y
Seines
Fly-shooting seine [SSC]
N
N
NA
?
Y
Anchored seine [SDN]
N
N
NA
?
Y
Pair-seine [SPR]
N
N
NA
?
Y
Beach and boat seine [SB]
[SV]
N
N
NA
?
?
Yes
N
NA
?
Y
Pelagic trawls
Traps
Nets
Recreational fisheries
ICES Advice 2012, Book 1
63
Table 2
North Sea (based on Anderson et al., 2011; Cosgrove and Browne, 2007; ICES, 2013a; Zydelis et al., 2013).
Threatened and declining
Gear groups
Dredges
Gear type
Birds
Mammals
Reptiles
Elasmobranch
Bony fish
Boat dredge [DRB]
N
N
NA
N
Y
Mechanized / Suction dredge
[HMD]
N
N
NA
N
N
Bottom otter trawl [OTB]
Y
N
NA
Y
Y
Multi-rig otter trawl [OTT]
?
N
NA
Y
Y
Bottom pair trawl [PTB]
?
N
NA
Y
Y
Beam trawl [TBB]
N
N
NA
Y
Y
Midwater otter trawl [OTM]
N
Y
NA
N
N
Midwater pair trawl [PTM]
N
Y
NA
N
N
Rods and Lines
Hand and Pole lines [LHP]
[LHM]
N
N
NA
N
N
Longlines
Set longlines [LLS]
?
N
NA
N
N
Traps
Pots and Traps [FPO]
N
Y
NA
N
N
Fykenets [FYK]
N
N
NA
?
?
Trammelnet [GTR]
Y
Y
NA
Y
Y
Set gillnet [GNS]
Y
Y
NA
Y
Y
Driftnet [GND]
Y
?
NA
N
N
Surrounding nets
Purse-seine [PS]
N
N
NA
Y
Y
Seines
Fly-shooting seine [SSC]
N
N
NA
Y
Y
Anchored seine [SDN]
N
N
NA
Y
Y
Pair-seine [SPR]
N
N
NA
Y
Y
Beach and boat seine [SB]
[SV]
N
N
NA
N
Y
N
N
NA
Y
N
Bottom trawls
Pelagic trawls
Nets
Recreational fisheries
64
ICES Advice 2013, Book 1
Table 1.5.2.2.3
Atlantic region (based on Anderson et al., 2011; Cosgrove and Browne, 2007; ICES, 2013a; Zydelis et al.,
2013).
Threatened and declining
Gear groups
Dredges
Gear type
Birds
Mammals
Reptiles
Elasmobranch
Bony fish
Boat dredge [DRB]
N
N
N
N
Y
Mechanized / Suction
dredge [HMD]
N
N
N
N
N
Bottom otter trawl [OTB]
Y
N
?
Y
Y
Multi-rig otter trawl [OTT]
?
N
N
Y
Y
Bottom pair trawl [PTB]
?
N
N
Y
Y
Beam trawl [TBB]
?
N
N
Y
Y
Midwater otter trawl
[OTM]
N
Y
N
Y
Y
Midwater pair trawl [PTM]
N
Y
N
Y
Y
Hand and Pole lines [LHP]
[LHM]
N
N
N
N
N
Trolling lines [LTL]
N
Y
N
N
N
Drifting longlines [LLD]
Y
N
N
N
N
Set longlines [LLS]
Y
N
N
N
N
Pots and Traps [FPO]
N
Y
Y
N
N
Fykenets [FYK]
N
N
N
N
N
Stationary uncovered
poundnets [FPN]
N
N
N
N
N
Trammelnet [GTR]
Y
Y
?
Y
Y
Set gillnet [GNS]
Y
Y
Y
Y
Y
Driftnet [GND]
Y
Y
Y
Y
N
Surrounding nets
Purse-seine [PS]
Y
Y
N
N
Y
Seines
Fly-shooting seine [SSC]
N
N
N
Y
Y
Anchored seine [SDN]
N
N
N
Y
Y
Pair-seine [SPR]
N
N
N
Y
Y
Beach and boat seine [SB]
[SV]
N
Y
N
N
N
N
N
N
N
N
Bottom trawls
Pelagic trawls
Rods and Lines
Longlines
Traps
Nets
Recreational fisheries
ICES Advice 2012, Book 1
65
Table 1.5.2.2.4
Mediterranean and Black Sea region (based on Casale, 2011; Cebrian Menchero, 2010; GFCM, 2008; ICES,
2013a; Tudela, 2004).
Threatened and declining
Gear groups
Gear type
Birds
Mammals
Reptiles
Elasmobranch
Bony fish
Dredges
Boat dredge [DRB]
N
N
N
N
?
Bottom trawls
Bottom otter trawl [OTB]
Y
Y
Y
Y
Y
Multi-rig otter trawl [OTT]
?
?
Y
Y
Y
Bottom pair trawl [PTB]
?
?
Y
Y
Y
Beam trawl [TBB]
N
N
N
Y
Y
Midwater otter trawl [OTM]
?
?
Y
Y
Y
Pelagic pair trawl [PTM]
?
Y
Y
Y
Y
Hand and Pole lines [LHP]
[LHM]
N
?
?
?
?
Trolling lines [LTL]
Y
?
?
?
?
Drifting longlines [LLD]
Y
Y
Y
Y
Y
Set longlines [LLS]
Y
Y
Y
Y
Y
Pots and Traps [FPO]
N
Y
N
N
?
Fykenets [FYK]
?
?
?
?
Stationary uncovered
poundnets [FPN]
?
?
Y
?
Trammelnet [GTR]
Y
Y
Y
Y
Y
Set gillnet [GNS]
Y
Y
Y
Y
Y
Driftnet [GND]
Y
Y
Y
Y
Y
Purse-seine [PS]
?
Y
Y
?
Y
Lampara nets [LA]
?
?
?
?
Y
Fly-shooting seine [SSC]
N
N
?
N
Y
Anchored seine [SDN]
N
N
?
N
Y
Pair-seine [SPR]
N
N
?
N
Y
Beach and boat seine [SB]
[SV]
N
N
?
?
?
?
Y
?
Y
?
Pelagic trawls
Rods and Lines
Longlines
Traps
Nets
Surrounding nets
Seines
Recreational fisheries
Y
Y
.
66
ICES Advice 2013, Book 1
Annex 2
Tables of fishing metiér and their potential to impact relevant benthic habitats
NA (not applicable) – the fishing metiér is not employed or would not contact the benthic habitat; N (no) – the fishing
metiér does contact, but does not impact, the benthic habitat; Y (yes) – a real or potential impact on the benthic habitat; ?
– the fishing metiér and benthic habitat are likely to overlap in space and time, but with insufficient information to make
a judgement. For the Mediterranean and Black Sea, the NA and N categories are combined as NA. Colours of fishing
gear cells symbolize level of activity: orange – common fishing gear/activity in this ecoregion; green – negligible or nonexistent; white – not known.
Table 1.5.2.2.5
Baltic Sea region
Gear group
Gear type
Seagrasses
Mud
Sea
pens
Sand
Gravel
Muddy
gravel
Mixed
sediments
Kelp
forests
Bivalve reefs
(Modiolus,
Musculus,
Ostrea)
Bottom trawls
Bottom otter
trawl [OTB]
NA
Y
NA
Y
Y
Y
Y
Y
NA
Multi-rig
otter trawl
[OTT]
Bottom pair
trawl [PTB]
NA
Y
NA
Y
Y
Y
Y
Y
NA
NA
Y
NA
Y
Y
Y
Y
Y
NA
Midwater
otter trawl
[OTM]
Midwater
pair trawl
[PTM]
Hand and
Pole lines
[LHP]
[LHM]
Drifting
longlines
[LLD]
Set longlines
[LLS]
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
N
N
N
N
N
N
N
N
N
NA
NA
NA
NA
NA
NA
NA
NA
NA
Y
?
?
N
?
?
?
Y
?
Pots and
Traps [FPO]
Y
?
?
N
?
?
?
Y
?
Fykenets
[FYK]
Y
?
?
N
?
?
?
Y
?
Stationary
uncovered
poundnets
[FPN]
Trammelnet
[GTR]
NA
NA
NA
NA
NA
NA
NA
NA
NA
Y
?
?
N
?
?
?
Y
?
Set gillnet
[GNS]
Y
?
?
N
?
?
?
Y
?
Surrounding
nets
Purse-seine
[PS]
?
?
?
?
?
?
?
?
?
Seines
Fly-shooting
seine [SSC]
Y
?
?
N
?
?
?
Y
?
Anchored
seine [SDN]
Y
?
?
N
?
?
?
Y
?
Pair-seine
[SPR]
Y
?
?
N
?
?
?
Y
?
Beach and
boat seine
[SB] [SV]
Recreational fisheries
Y
?
?
N
?
?
?
Y
?
?
N
?
N
N
N
N
Y
Y
Pelagic trawls
Rods and Lines
Longlines
Traps
Nets
ICES Advice 2013, Book 1
67
Table 1.5.2.2.6
North Sea
Gear groups
Gear type
Hard
biogeni
c reefs
(Lophe
lia,
carbon
ate
mound
s,
maerl,
etc.)
Sabe
llari
a
reefs
Seagrass
es
Mu
d
Sea
pen
s
Sa
nd
Gra
vel
Mudd
y
grave
l
Mixe
d
sedi
ment
s
Kel
p
fore
sts
Circa
littora
l
reefs
incl.
coral
garde
ns,
spong
es
Bivalv
e reefs
(Modio
lus,
Muscul
us,
Ostrea
)
Deepwater
spong
es
Dredges
Boat dredge [DRB]
Y
?
?
Y
Y
Y
Y
Y
Y
Y
NA
Y
Y
Mechanized /
Suction dredge
[HMD]
NA
NA
NA
NA
?
Y
NA
NA
Y
NA
NA
NA
NA
Bottom otter trawl
[OTB]1
Y
Y
NA
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Multi-rig otter
trawl [OTT]
Y
Y
NA
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Bottom pair trawl
[PTB]
Y
Y
NA
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Beam trawl [TBB]
Y
Y
NA
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Midwater otter
trawl [OTM]
NA
NA
NA
NA
NA
N
A
NA
NA
NA
NA
NA
NA
NA
Midwater pair
trawl [PTM]
NA
NA
NA
NA
NA
N
A
NA
NA
NA
NA
NA
NA
NA
Rods and Lines
Hand and Pole
lines [LHP] [LHM]
N
N
N
N
N
N
N
N
N
N
N
N
N
Longlines
Set longlines [LLS]
Y
Y
Y
?
?
N
?
?
?
?
Y
?
Y
Traps
Pots and Traps
[FPO]
Y
Y
Y
?
?
N
?
?
?
Y
Y
?
Y
Fykenets [FYK]
NA
NA
N
?
NA
N
N
N
?
NA
NA
?
NA
Trammelnet [GTR]
Y
Y
Y
?
?
N
?
?
?
Y
Y
?
Y
Set gillnet [GNS]
Y
Y
Y
?
?
N
?
?
?
Y
Y
?
Y
Driftnet [GND]
N
N
N
N
N
N
N
N
N
N
N
N
N
Surrounding
nets
Purse-seine [PS]
N
N
N
?
?
?
?
?
?
N
N
N
N
Seines
Fly-shooting seine
[SSC]
Y
Y
Y
?
?
N
?
?
?
Y
Y
?
Y
Anchored seine
[SDN]
Pair-seine [SPR]
Y
Y
Y
?
?
N
?
?
?
Y
Y
?
Y
Y
Y
Y
?
?
N
?
?
?
Y
Y
?
Y
Beach and boat
seine [SB] [SV]
Y
Y
Y
?
?
N
?
?
?
Y
Y
?
Y
Y
?
?
N
?
N
N
N
N
?
Y
Y
NA
Bottom trawls
Pelagic trawls
Nets
Recreational fisheries
68
ICES Advice 2013, Book 1
Table 1.5.2.2.7
Atlantic region
Gear group
Gear type
Dredges
Boat dredge
[DRB]
Bivalv
e reefs
(Modi
olus,
Muscu
lus,
Ostrea
)
Deep
water
spong
es
NA
Circ
alittor
al
reefs
incl.
coral
gard
ens
NA
Y
?
Y
NA
NA
NA
NA
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
N
N
N
N
N
N
N
N
N
N
N
N
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
Drifting longlines
[LLD]
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
Set longlines
[LLS]
Y
Y
Y
?
?
?
?
?
?
Y
Y
?
Y
Pots and Traps
[FPO]
Y
Y
Y
?
?
?
?
?
?
Y
Y
?
Y
Fykenets [FYK]
NA
NA
N
?
NA
N
N
N
?
NA
NA
?
NA
Stationary
uncovered
poundnets [FPN]
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
Trammelnet
[GTR]
Y
Y
NA
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Set gillnet [GNS]
Y
Y
?
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Driftnet [GND]
N
N
N
N
N
N
N
N
N
N
N
N
N
Surrounding
nets
Purse-seine [PS]
N
N
N
?
?
?
?
?
?
N
N
N
N
Seines
Fly-shooting seine
[SSC]
Y
Y
Y
?
?
N
?
?
?
Y
Y
?
NA
Anchored seine
[SDN]
Y
Y
Y
?
?
N
?
?
?
Y
Y
?
NA
Pair-seine [SPR]
Y
Y
Y
?
?
N
?
?
?
Y
Y
?
NA
Beach and boat
seine [SB] [SV]
Y
Y
Y
?
?
N
?
?
?
Y
Y
?
NA
Y
?
?
N
?
N
N
N
N
Y
Y
Y
NA
Bottom trawls
Pelagic trawls
Rods and Lines
Longlines
Traps
Nets
Hard
biogeni
c reefs
(Lophe
lia,
carbon
ate
mound
s
Y
Sabel
laria
reefs
Sea
gras
ses
Mu
d
Sea
pen
s
San
d
Gra
vel
Mudd
y
grave
l
Mixe
d
sedim
ents
Kel
p
fore
sts
Y
Y
Y
Y
Y
Y
Y
Y
Mechanized /
Suction dredge
[HMD]
N
N
N
N
N
Y
?
Y
Bottom otter trawl
[OTB]
Y
Y
NA
Y
Y
Y
Y
Multi-rig otter
trawl [OTT]
Y
Y
NA
Y
Y
Y
Bottom pair trawl
[PTB]
Y
Y
NA
Y
Y
Beam trawl [TBB]
Y
Y
NA
Y
Midwater otter
trawl [OTM]
NA
NA
NA
Midwater pair
trawl [PTM]
NA
NA
Hand and Pole
lines [LHP]
[LHM]
N
Trolling lines
[LTL]
Recreational fisheries
ICES Advice 2013, Book 1
69
Table 1.5.2.2.8
Gear
groups
Mediterranean and Black Sea (based on Tudela, 2004; Bazairi et al., 2010).
Gear type
INFRALITTORAL
CIRCALITTORAL
BATHYAL
ABYSSA
L
Fine
muddy
-sands
Coarse
sands
in very
shallo
w
waters
Stones and
pebbles
(incl.
biogenic
reefs:
maerl,
Rhodolites
, etc.)
Posidoni
a
oceanica
meadows
Hard Mud
beds s
and
rock
s
Sand
s
Hard beds
and rocks
(coralligenous
)
Mud
s
Sand
s
hard
rocks
(incl.
deepsea
corals
)
Muds
Dredges
Boat
dredge
[DRB]
Y
NA
?
NA
NA
Y
Y
Y
NA
NA
NA
NA
Bottom
trawls
Bottom
otter trawl
[OTB]
Y
NA
Y
Y
NA
Y
Y
Y
Y
Y
Y
NA
Multi-rig
otter trawl
[OTT]
Y
NA
?
Y
NA
Y
Y
?
Y
Y
Y
NA
Bottom pair Y
trawl [PTB]
NA
?
Y
NA
Y
Y
?
Y
Y
Y
NA
Beam trawl
[TBB]
Y
NA
?
NA
NA
Y
Y
Y
NA
NA
NA
NA
Midwater
otter trawl
[OTM]
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
Pelagic pair NA
trawl
[PTM]
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
Hand and
Pole lines
[LHP]
[LHM]
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
Trolling
lines [LTL]
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
Drifting
longlines
[LLD]
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
Set
longlines
[LLS]
?
?
?
?
?
?
?
?
NA
NA
NA
NA
Pots and
Traps
[FPO]
Y
?
Y
?
Y
Y
Y
Y
NA
NA
NA
NA
Fykenets
[FYK]
Y
?
Y
?
?
Y
Y
Y
NA
NA
NA
NA
Stationary
uncovered
poundnets
[FPN]
?
?
?
?
?
?
?
?
NA
NA
NA
NA
Trammelne
t [GTR]
Y
Y
Y
Y
Y
Y
Y
Y
NA
NA
NA
NA
Set gillnet
[GNS]
Y
Y
Y
Y
Y
Y
Y
Y
NA
NA
NA
NA
Driftnet
[GND]
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
Purse-seine
[PS]
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
Lampara
nets [LA]
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
?
Flyshooting
seine [SSC]
?
?
?
?
?
?
?
NA
NA
NA
NA
?
?
?
?
?
?
?
?
NA
NA
NA
NA
Pelagic
trawls
Rods and
Lines
Longlines
Traps (d)
Nets
Surrounding
nets
Seines
Anchored
seine
[SDN]
70
ICES Advice 2013, Book 1
Gear
groups
Gear type
INFRALITTORAL
CIRCALITTORAL
BATHYAL
ABYSSA
L
Fine
muddy
-sands
Coarse
sands
in very
shallo
w
waters
Stones and
pebbles
(incl.
biogenic
reefs:
maerl,
Rhodolites
, etc.)
Posidoni
a
oceanica
meadows
Hard Mud
beds s
and
rock
s
Sand
s
Hard beds
and rocks
(coralligenous
)
Mud
s
Sand
s
hard
rocks
(incl.
deepsea
corals
)
Muds
Pair-seine
[SPR]
?
?
?
?
?
?
?
?
NA
NA
NA
NA
Beach and
boat seine
[SB] [SV]
?
?
NA
Y
?
NA
NA
NA
NA
NA
NA
NA
?
?
?
?
Y
?
?
?
NA
NA
NA
NA
Recreational fisheries
ICES Advice 2013, Book 1
71
1.5.3 HELCOM
No advice has been requested for 2013
1.5.4 NASCO
The advice provided in response to special requests from the North Atlantic Salmon Conservation Organisation (NASCO)
can be found in Book 10 of the ICES Advice 2013 Report.
72
ICES Advice 2013, Book 1
1.5.5 NEAFC
1.5.5.1
ECOREGION
SUBJECT
Special request, Advice June 2013
General advice
Vulnerable deep-water habitats in the NEAFC Regulatory Area
Advice summary
ICES advises that new data are available on the presence of VMEs in the NEAFC Regulatory Area. ICES advises NEAFC
that new closures to bottom fisheries or revision of existing closure boundaries in the following five areas would enable
the protection of these VMEs.
•
•
•
•
•
Northwest Rockall Bank;
Southwest Rockall Bank;
Hatton–Rockall Basin;
Hatton Bank;
Josephine Seamount.
Request
NEAFC requests ICES to continue to provide all available new information on distribution of vulnerable habitats in the
NEAFC Convention Area and fisheries activities in and in the vicinity of such habitats.
ICES advice
New information on the location of vulnerable habitats in the NEAFC Regulatory Area
New data that indicate the presence of vulnerable habitats (i.e. VMEs) were submitted to ICES in 2013. Some of these
data are in the NEAFC Regulatory Area (NEAFC RA).
Five areas are detailed below which contain information on new findings of VMEs, and potential closure boundaries are
advised. ICES has no new information (i.e. VMS data) available on actual fishing activity in these areas at the spatial
resolution required to evaluate the pressure on the habitats.
1) Northwest Rockall Bank
Rockall Bank is a large plateau that lies partly in EU waters and partly in international waters regulated by NEAFC. An
area in the northwestern part of Rockall Bank has been closed to bottom fishing since 2007 for the protection of VMEs.
In 2012, ICES advised a boundary modification to the area based on new information. Six further video transects within
or close to the Northwest Rockall Bank closure were completed in 2012 (Figure 1.5.5.1.1). The video footage revealed
extensive patches of coral reefs in the centre and toward the southern end (that which lies within the NEAFC RA) of the
current closure. In part of the proposed eastern extension to the closure to bottom fishing advised by ICES in 2012, a
video transect revealed new observations of coral reefs, reaffirming the appropriateness of this extension. No VMEs were
observed in a transect to the north of the closure.
ICES reiterates its advice from 2012 to extend the closure. The boundary of this closure is detailed in Figure 1.5.5.1.1
and Table 1.5.5.1.1.
ICES Advice 2013, Book 1
73
Figure 1.5.5.1.1
74
Map of NW Rockall Bank showing locations of video transects and new findings of VMEs.
ICES Advice 2013, Book 1
Table 1.5.5.1.1
P OINT N UMBER
2)
Coordinates of points for recommended closure to bottom fishing in Northwest Rockall Bank.
L ATITUDE (N) (DEGREES MINUTES
S ECONDS)
L ONGITUDE (W) (D EGREES MINUTES
S ECONDS)
L ATITUDE ( DECIMAL )
L ONGITUDE ( DECIMAL )
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
58 02 49.20
57 51 35.92
57 47 50.42
57 43 22.15
57 37 15.49
57 42 33.62
57 49 48.97
57 56 05.67
57 53 37.50
57 50 05.13
57 45 18.43
57 28 59.98
57 22 00.01
56 55 59.98
56 55 59.98
57 00 00.00
57 37 00.01
57 50 15.79
57 50 42.00
57 59 35.30
58 09 29.55
58 13 05.91
58 13 43.32
58 12 14.22
13 22 25.96
13 07 30.14
13 02 59.42
13 02 17.37
13 14 55.75
13 16 28.56
13 23 09.02
13 43 26.11
13 52 28.16
13 56 22.56
14 08 24.00
14 19 00.01
14 19 00.01
14 36 00.00
14 51 00.00
14 52 59.98
14 42 00.00
14 28 44.22
14 28 25.86
14 23 11.18
14 03 48.85
13 53 17.88
13 49 41.37
13 43 52.32
58.04700
57.85998
57.79734
57.72282
57.62097
57.70934
57.83027
57.93491
57.89375
57.83476
57.75512
57.48333
57.36667
56.93333
56.93333
57.00000
57.61667
57.83772
57.84500
57.99314
58.15821
58.21831
58.22870
58.20395
-13.37388
-13.12504
-13.04984
-13.03816
-13.24882
-13.27460
-13.38584
-13.72392
-13.87449
-13.93960
-14.14000
-14.31667
-14.31667
-14.60000
-14.85000
-14.88333
-14.70000
-14.47895
-14.47385
-14.38644
-14.06357
-13.88830
-13.82816
-13.73120
25
58 07 11.71
13 34 29.10
58.11992
-13.57475
Southwest Rockall Bank
In the southwestern section of Rockall Bank a closure to bottom fisheries has been in effect since 2007 to protect VMEs.
New data were available from three towed video transects in 2012 (Figure 1.5.5.1.2). Coral reefs were recorded, as were
extensive stretches of seabed without coral reefs. Most of the coral reefs recorded were inside the currently closed area,
but some were observed outside the currently closed area. If NEAFC wishes to protect these VMEs, ICES advises
NEAFC:
1) to extend the boundary of the closure in the western corner to incorporate the new video records.
2) to extend the boundary in the southern corner to encompass new video records and the 2012 bycatch records.
Boundaries recommended by ICES have been drawn to include a buffer zone of three times the water depth. In the
northern part of the Southwest Rockall Bank closed area there is now some video evidence that coral reefs are not present
in an area where they have previously been reported. Should further research (including analysis of fishing data)
demonstrate the absence of VMEs, this area may be considered for reopening to bottom fishing in the future.
ICES Advice 2013, Book 1
75
Figure 1.5.5.1.2
Southwest Rockall Bank bottom fishing closure boundary modifications.
The geographic coordinates for the two closure extensions are provided in Tables 1.5.5.1.2 and 1.5.5.1.3.
76
ICES Advice 2013, Book 1
Table 1.5.5.1.2
Geographic coordinates for the Southwest Rockall Bank western closure extension.
L ATITUDE ( DECIMAL DEGREES)
L ONGITIDE ( DECIMAL DEGREES)
L ATITUDE (DMS)
L ONGITUDE (DMS)
55.9694
55.9706
-16.2196
-16.0427
55° 58' 10" N
55° 58' 14" N
16° 13' 11" W
16° 2' 34" W
55.9144
-16.0925
55° 54' 52" N
16° 5' 33" W
Table 1.5.5.1.3
Geographic coordinates for the Southwest Rockall Bank southern corner closure extension.
L ATITUDE ( DECIMAL DEGREES)
L ONGITIDE ( DECIMAL DEGREES)
L ATITUDE (DMS)
L ONGITUDE (DMS)
55.9310
55.8500
55.7977
-15.6806
-15.6167
-15.8968
55° 55' 52" N
55° 51' 0" N
55° 47' 52" N
15° 40' 50" W
15° 37' 0" W
15° 53' 48" W
55.8215
-15.9399
55° 49' 17" N
15° 56' 24" W
3) Hatton–Rockall Basin
The Hatton-Rockall basin is an expanse of deep-water sedimentary habitat of depths between 1100–1500 m. In a research
survey in 2012, a benthic sampling net contained at least two undescribed species of a genus of chemosymbiotic clams.
To date, species from this genus have only been found in association with active cold seeps/gas hydrate ecosystems. This
is the first indication of an active cold seep ecosystem at the Hatton–Rockall Basin. Cold seeps are considered to be VMEs
under the FAO guidelines and since the site is at approximately 1200 m depth, it is vulnerable to bottom contact fishing.
Estimates from the Ship’s log and sensors attached to the net give an approximate position with a radial uncertainty of
around 3 km (Figure 1.5.5.1.3). Should NEAFC wish to protect this VME, ICES advises a closure to bottom fisheries
centred around the circle in Figure 1.5.5.1.3 with a buffer zone of 2400 m (twice water depth), corresponding to the
coordinates in Table 1.5.5.1.4. Future research should be able to provide a more precise location and estimate of the extent
of the ecosystem, at which point the appropriateness of the closure boundary can be assessed.
Figure 1.5.5.1.3
Approximate location of chemosynthetic clams found within the Hatton–Rockall Basin.
ICES Advice 2013, Book 1
77
Table 1.5.5.1.4
Geographic coordinates for the advised closure.
POINT
DECIMAL
DECIMAL
LATITUDE
LONGITUDE
1
58.0025
-15.4538
2
58.0025
-15.6377
3
57.90317
-15.4538
4
57.90317
-15.6377
Howell et al. (2013) observed aggregations of sponges in visual surveys in the centre of the Hatton–Rockall Basin at
approximately 1150 m water depth. Should NEAFC want to protect these VMEs, ICES advises a closure to bottom fishing
for the area shown in Figure 1.5.5.1.4, with the geographic coordinates provided in Table 1.5.5.1.5.
Figure 1.5.5.1.4
Location of sponge aggregations at the Hatton–Rockall Basin with the advised closure boundary.
Table 1.5.5.1.5
Geographic coordinates for the advised Hatton–Rockall Basin closure.
L ATITUDE ( DECIMAL DEGREES)
L ONGITUDE ( DECIMAL DEGREES)
L ATITUDE (DMS)
L ONGITUDE (DMS)
58.1840
58.2166
58.1832
-16.5190
-16.4205
-16.3624
58° 11' 2" N
58° 12' 60" N
58° 10' 59" N
16° 31' 8" W
16° 25' 14" W
16° 21' 45" W
58.1348
-16.4511
58° 8' 5" N
16° 27' 4" W
4) Hatton Bank
This year no new VME data were available for the Hatton Bank area, but new information in graphic format was provided
on Spanish fishing activity for the period 2000–2011 (Figure 1.5.5.1.5). This clearly demonstrates where the fishing
activity occurs and highlights the southwestern slopes of the Hatton Bank as areas where VMEs are unlikely to be present
due to intensive trawling. Therefore ICES considers that Area 3 in Figure 1.5.5.1.5 requires modifications (a reduction in
the VME closed area) to reflect this. ICES assessed the significance of bycatch levels of seapens against the NAFO
threshold levels and determined that the records of seapens on the southwestern slopes of Hatton Bank are insufficient to
describe the area as a VME.
Based on the information on where Spanish vessels fish and existing information on VMEs in the area, ICES advises that
two areas, one to the southeast (Figure 1.5.5.1.6 and Table 1.5.5.1.6) and one to the southwest (Figure 1.5.5.1.6 and Table
1.5.5.1.7) of Hatton Bank would be suitable for closure to bottom fishing, should NEAFC wish to protect these VMEs.
The closure boundaries are based on:
i.
ii.
78
The presence of carbonate mounds which classify as VME elements (area to the southwest of Hatton Bank);
The presence of large bycatch (exceeding 400 kg) of sponges in the east (area to the southeast of Hatton Bank);
ICES Advice 2013, Book 1
iii.
iv.
v.
vi.
vii.
The presence of small bycatch of gorgonians in the area (area to the southwest of Hatton Bank);
A ‘knoll’ area (VME element) to the southwest of Hatton Bank, visible from the bathymetric data and records
of gorgonians from the summit (< 1000 m);
Two areas of outcropped rock (VME elements) on the western slope, evident from multibeam data;
Evidence of fishing (trawling) activity in the sedimentary areas (Hatton Drift) of the western slope (see Figure
1.5.5.1.5);
All VME indicator records outside the advised closed area are below the threshold used to determine the presence
of VMEs by NAFO or the current thresholds adopted by NEAFC.
Figure 1.5.5.1.5
Fishery footprint for the Spanish bottom-trawl fishery (period 2000–2011), based on VMS data
provided by the Spanish Government (modified from Durán Muñoz et al., 2012). Grey patches and
points are VMS data (speed = 2–4 knots); Black crosses are absence of VME indicator taxa records
in the bycatch; Triangles are records of cold-water corals pooled; Circles are records of sponges
pooled; Squares are carbonate mounds (VME records from ICES database). The NEAFC closed
area is represented by the purple polygons. An area advised for closure by ICES in 2012 is indicated
by the black polygon. A multibeam bathymetry map provided by the Instituto Español de
Oceanografía (IEO) showing the western slope of the bank is also presented.
ICES Advice 2013, Book 1
79
Figure 1.5.5.1.6
The two areas of Hatton Bank proposed to be closed to bottom fishing, one to the southeast (blue
boundary) and one to the southwest (yellow boundary). Where the boundary was drawn around
VME indicator species a buffer of twice the depth is included.
Table 1.5.5.1.6
Geographic coordinates for the advised closure extension to the southeast of Hatton Bank.
L ATITUDE ( DECIMAL DEGREES)
L ONGITUDE ( DECIMAL DEGREES)
L ATITUDE (DMS)
L ONGITUDE (DMS)
57.8626
57.9167
58.0500
57.8850
-18.0978
-17.5000
-17.5000
-16.9388
57° 51' 45" N
57° 54' 60" N
58° 3' 0" N
57° 53' 6" N
18° 5' 52" W
17° 29' 60" W
17° 30' 0" W
16° 56' 20" W
57.5851
-18.0335
57° 35' 6" N
18° 2' 0" W
80
ICES Advice 2013, Book 1
Table 1.5.5.1.7
Geographic coordinates for the advised closure extension to the soutwest of Hatton Bank.
L ATITUDE ( DECIMAL DEGREES)
L ONGITUDE ( DECIMAL DEGREES)
L ATITUDE (DMS)
L ONGITUDE (DMS)
57.9993
57.7500
57.8345
57.5188
57.2348
57.0368
56.8853
56.8370
56.7780
57.0007
57.1718
57.5445
-19.0842
-19.2500
-18.3970
-18.3547
-19.4738
-19.4588
-19.4828
-19.5604
-19.8954
-20.0704
-19.9207
-19.8773
57° 59' 58" N
57° 44' 60" N
57° 50' 4" N
57° 31' 8" N
57° 14' 5" N
57° 2' 12" N
56° 53' 7" N
56° 50' 13" N
56° 46' 41" N
57° 0' 2" N
57° 10' 18" N
57° 32' 40" N
19° 5' 3" W
19° 15' 0" W
18° 23' 49" W
18° 21' 17" W
19° 28' 26" W
19° 27' 32" W
19° 28' 58" W
19° 33' 37" W
19° 53' 43" W
20° 4' 13" W
19° 55' 15" W
19° 52' 38" W
57.7780
-19.6310
57° 46' 45" N
19° 37' 46" W
5) Josephine Seamount
Josephine Seamount is one of six seamounts included in a cluster just over 200 nm north of the Island of Madeira.
Josephine Seamount is classed by NEAFC as ‘an existing bottom fishing area’. In 2011, OSPAR designated the Josephine
Seamount (and the five other seamounts in the immediate vicinity) as an MPA on the basis of information that included
VME indicator species such as hexactinellid sponges and gorgonians (OSPAR, 2011). In 2012, ICES presented further
historical evidence showing the presence of gorgonians on and around the Josephine Seamount. Taken together, these
data indicate that there is a high likelihood that Josephine and the surrounding seamounts have VMEs. ICES did not have
access to recent data on fishing activity for this area and thus cannot directly assess the risk of impact to these VMEs.
However, in view of the present status of the Josephine Seamount MPA as an ‘existing fishing area’, ICES considers that
there is a risk of significant adverse impacts to VMEs in the area from bottom fishing gears.
Should NEAFC wish to protect these VMEs, ICES advises a closure to bottom fisheries, the boundary of which should
correspond to the Josephine Seamount High Seas MPA established by OSPAR (OSPAR Decision 2010/5) (Figure
1.5.5.1.7 and Table 1.5.5.1.8). Such a closure would encompass the seamount, the documented locations of recent VME
indicator records, and the five other nearby seamounts that are within the NEAFC RA. As a consequence of enclosing the
seamounts in one protective management measure, some surrounding deep areas of high topographic relief (and thus
likely to contain VMEs) would also be protected from potential impacts.
Figure 1.5.5.1.7
Table 1.5.5.1.8
Map of Josephine Seamount showing the distribution of gorgonian corals and the proposed bottom
fishing closure that corresponds precisely with the OSPAR High Seas MPA. The red square in the
overview map shows the approximate location of the closure.
Geographic coordinates for the proposed Josephine Seamount NEAFC bottom fishing closure.
ICES Advice 2013, Book 1
81
L ATITUDE ( DECIMAL DEGREES)
L ONGITUDE ( DECIMAL DEGREES)
L ATITUDE (DMS)
L ONGITUDE (DMS)
37.460
37.630
36.860
36.180
36.450
-14.650
-13.750
-13.420
-14.450
-15.390
37° 27' 36" N
37° 37' 48" N
36° 51' 36" N
36° 10' 48" N
36° 27' 0" N
14° 39' 0" W
13° 45' 0" W
13° 25' 12" W
14° 26' 60" W
15° 23' 24" W
36.760
-15.720
36° 45' 36" N
15° 43' 12" W
ICES recommendation
NEAFC has requested ICES to provide all available new information on fisheries activities in, and in the vicinity of, VME
habitats. ICES cannot address this request further without data on fishing activities at high spatial resolution. ICES
therefore recommends that all recent VMS data in the NEAFC RA are made available. This data should include
information on gear type and vessel speed in order to define the impact on the VMEs by bottom trawling and by longlines.
Sources
Durán Muñoz, P., Sacau, M., and Sayago-Gil, M., on behalf of the ECOVUL/ARPA Team. 2012. The EU’s experience
in the protection of cold-water corals in the high seas: The Hatton Bank (NEAFC Regulatory Area) – a case study.
NEAFC–PECMAS symposium on its bottom fisheries. North East Atlantic Fisheries Commission. London, 25 June
2012.
Howell, K. L., Huvenne, V., Piechaud, N., Roberts, K., and Ross, R. 2013. JC060 Data Analysis: Comprising data from
Darwin Mounds (NE Rockall Trough), Rockall–Hatton Basin Polygonal Faults, NW Rockall Bank, and E Rockall
Bank Escarpment. Report to the Joint Nature Conservation Committee. Unpublished.
ICES 2013. Report of the ICES/NAFOJoint Working Group on Deep-water Ecology (WGDEC). ICES CM 2013/ACOM:
28.
OSPAR. 2011. Background document on the Josephine Seamount Marine Protected Area.
82
ICES Advice 2013, Book 1
1.5.5.2
Special request, Advice June 2013
ECOREGION
SUBJECT
General advice
Evaluation of the appropriateness of buffer zones
Advice summary
Both the VME location accuracy and a buffer zone are considered when delineating the closure boundary around VMEs.
ICES is confident that the buffer zone considerations used to define the boundaries around the area closures are
appropriate and therefore adequate for the protection of VMEs. A schematic diagram of the approach to generate buffer
zones is presented. The buffer zones will always be included in ICES advice and will be illustrated where appropriate to
the scale of the closure.
Request
ICES is requested to evaluate whether buffer zones applied in the current bottom fishing closures are appropriate.
Additionally, ICES is requested to include, specify and illustrate buffer zones in its future advice on closures in the
Regulatory Area as appropriate.
Advice
Two different considerations are used to delineate buffer zones around VMEs; one is linked to the VME location accuracy,
the other to setting a buffer zone around the VME location (Figure 1.5.5.2.1).
Example 1
Example 2
Example 3
Estimated location of VME
Trawl track
VME area
Buffer zone
Figure 1.5.5.2.1
Three conceptual examples of the two considerations for delineating buffer zones around VMEs,
applied to three theoretical examples of VME closures. Example 1: isolated VME detection with
low geospatial certainty (e.g. trawl track); Example 2: isolated VME detection with high geospatial
certainty (e.g. ROV observation); and Example 3: area identified as hosting a VME.
Consideration 1. VME location accuracy
The data used by ICES to assess the likelihood of VME presence consists of mainly point records of species (Figure
1.5.5.2.1). While recognising this is the best available data, there are varying levels of spatial uncertainty associated with
the records, ranging from trawl bycatch with low spatial accuracy (Example 1) to dynamically positioned ROV
observations with high spatial accuracy (Example 2) and areas identified as hosting VMEs (Example 3). This uncertainty
in VME location is dealt with by outlining the minimum boundary that encompasses the records. In the case of records
derived from trawling, the deviation perpendicular to the track is considered negligible relative to the length of the track
and is not taken into account in the VME location.
While spatial accuracy of the position of VMEs has improved over time, there are still a high number of records where
the location accuracy is unknown. In such cases a simple buffer is applied (see Consideration 2).
Consideration 2. Buffer zone around VME location
ICES considers a buffer zone to be a spatial margin of assurance around the VME to avoid adverse impact (Figure
1.5.5.2.1). The spatial extension of the buffer zone may vary and is based on the following:
•
The potential for fishing gear to stray into the VME is related to the uncertainty of the location of the fishing
gear relative to the known location of the vessel. This will be a function of water depth and the trawl warp length
deployed. In deep-water trawling, the typical warp length deployed decreases with water depth, from around 3:1
ICES Advice 2013, Book 1
83
•
•
at 200 m to 2:1 at 500 m and more. For VMEs that occur on flat or undulating seabed a buffer zone of
approximately two (>500 m depth) or three times (< 500 m depth) the local depth is advised.
In the case of VMEs on very steep slopes, the risk of straying of bottom trawls is mitigated by the fishers’ own
incentive to avoid the steep slopes and cliff edges, in which case the buffer zone may be reduced.
In some cases the presence of geomorphological features are used to define boundaries for closures on the basis
that they are considered to be VME elements, in which case the VME reflects the topographic relief of the VME
element without a buffer zone.
As both the VME location accuracy and a buffer zone are considered when advising on a closure boundary around VMEs,
ICES is confident that the buffer zone considerations used to extend closures beyond the immediate estimated position of
a VME are appropriate and therefore adequate for the protection of VMEs.
The buffer zone approach described here does not take into account any issues specifically related to enforcement.
Source
ICES 2013. Report of the ICES/NAFO Joint Working Group on Deep-water Ecology (WGDEC). ICES CM 2013/ACOM:
28.
84
ICES Advice 2013, Book 1
1.5.5.3
ECOREGION
SUBJECT
Special request, Advice June 2013
General advice
Assessment of the list of VME indicator species and elements
Advice summary
1) Taxa should be considered by habitat type and/or at the taxonomic level of family rather than listing all the likely
species that would be indicators of VMEs in the NEAFC Regulatory Area (RA). A table of relevant families and
habitat types is provided.
2) Three maps of VME elements in the NEAFC RA at depths less than 2000 m, including the Mid-Atlantic Ridge,
the Rockall–Hatton area, and isolated seamounts, are provided. Canyon-like features and steep flanks and slopes
are known only from the Mid-Atlantic Ridge and the Rockall–Hatton area. There is not sufficient information
to map all knolls.
3) There are only five known or inferred vent sites within the NEAFC RA. The vent sites, other than the one inferred
site on the Reykjanes Ridge, are below 2000 m depth and are not likely to be impacted by fishing activities. It is
advised that the site on the Reykjanes Ridge be closed to bottom-contacting gear.
Request
1) ICES is requested to assess whether the list of VME indicator species is exhaustive and suggest possible addition
to that list. The basis for the assessment should be the FAO Guidelines specifying taxa and habitats that may be
relevant. ICES should focus on taxa (species or assemblages of species) that tend to form dense aggregations of
assumed particular functional significance. NAFO SC has in 2012 conducted a similar assessment and revision
and to the extent scientifically valid harmonization with NAFO lists would be beneficial.
2) ICES is furthermore asked to map VME elements (i.e. geomorphological features) in the NEAFC RA. This would
include seamounts and knolls at fishable depths (with summits shallower than 2000m), canyons, and steep flanks.
Also in this exercise, harmonization with NAFO SC evaluations would be beneficial.
3) ICES is specifically requested to advise NEAFC on the occurrence of hydrothermal vents and measures
applicable to protect hydrothermal vents and associated communities in the RA.
ICES advice
1) VME indicator species
ICES advises that in the NEAFC RA, VME indicators should be considered by habitat type and/or at the taxonomic level
of family rather than by an exhaustive list of all likely species that could be indicators of VMEs. This approach avoids
the risk of excluding or misidentifying any potential species, while ensuring that VMEs are appropriately recognised.
Table 1.5.5.3.1 lists seven VME habitat types for the Northeast Atlantic with the taxa that are most likely to be found in
these habitats. For comparison and harmonization the equivalent set of species from the NAFO list is also presented. All
the habitats listed in Table 1.5.5.3.1 should contain significant aggregations of the representative taxa, and those taxa will
most commonly meet the criteria of long-lived, functional significance or fragility. For the most part the families in both
NEAFC and NAFO areas are comparable, but there are differences at species level.
ICES Advice 2013, Book 1
85
Table 1.5.5.3.1
List of deep-water VMEs and their characteristic taxa. NAFO species have been aligned with the
proposed VME habitat type for NEAFC and their representative taxa. In some VME habitat types,
no species were listed by the NAFO Scientific Council.
P ROPOSED NEAFC VME HABITAT
T YPE
R EPRESENTATIVE NEAFC
T AXA
C ORRESPONDING NAFO SPECIES
1. Cold-water coral reef
A. Lophelia pertusa reef
Lophelia pertusa
Lophelia pertusa*
Solenosmilia variabilis
Solenosmilia variabilis*
ANTHOTHELIDAE
ANTHOTHELIDAE
Anthothela grandiflora*
CHRYSOGORGIIDAE
Chrysogorgia sp.
Metallogorgia melanotrichos
Iridogorgia sp.
ISIDIDAE, KERATOISIDINAE
Acanella arbuscula
Acanella eburnea
Keratoisis ornata*
Keratoisis sp.*
Lepidisis sp.
PLEXAURIDAE
Swiftia sp.*
Paramuricea grandis
Paramuricea placomus*
Paramuricea sp.
Placogorgia sp.
Placogorgia terceira
ACANTHOGORGIIDAE
Acanthogorgia armata*
CORALLIIDAE
Corallium bathyrubrum
Corallium bayeri
PARAGORGIIDAE
Paragorgia arborea*
Paragorgia johnsoni
PRIMNOIDAE
Calyptrophora sp.
Parastenella atlantica
Primnoa resedaeformis*
Thouarella grasshoffi
Narella laxa
B. Solenosmilia variabilis reef
2. Coral garden
A. Hard-bottom coral garden
i. Hard-bottom gorgonian and
black coral gardens
CHRYSOGORGIIDAE
ISIDIDAE,
KERATOISIDINAE
PLEXAURIDAE
ACANTHOGORGIIDAE
CORALLIIDAE
PARAGORGIIDAE
PRIMNOIDAE
SCHIZOPATHIDAE
ii. Colonial scleractinians on rocky
outcrops
Lophelia pertusa
Solenosmilia variabilis
iii. Non-reefal scleractinian aggregations
Enallopsammia rostrata
Madrepora oculata
Enallopsammia rostrata
Madrepora oculata*
CHRYSOGORGIIDAE
CHRYSOGORGIIDAE
Radicipes gracilis*
CARYOPHYLLIIDAE
FLABELLIDAE
---------
B. Soft-bottom coral gardens
i. Soft-bottom gorgonian and black coral
gardens
ii. Cup-coral fields
86
ICES Advice 2013, Book 1
P ROPOSED NEAFC VME HABITAT
T YPE
R EPRESENTATIVE NEAFC
T AXA
C ORRESPONDING NAFO SPECIES
iii. Cauliflower coral fields
NEPHTHEIDAE
-----
3. Deep-sea sponge aggregations
A. Ostur sponge aggregations
GEODIIDAE
GEODIIDAE
Geodia barretti*
Geodia macandrewii*
Geodia phlegraei*
ANCORINIDAE
Stelletta normani*
Stelletta sp.
Stryphnus ponderosus*
PACHASTRELLIDAE
Thenea muricata*
ANCORINIDAE
PACHASTRELLIDAE
B. Hard-bottom sponge gardens
----AXINELLIDAE
----MYCALIDAE
POLYMASTIIDAE
TETILLIDAE
C. Glass sponge communities
4. Seapen fields
ROSSELLIDAE
PHERONEMATIDAE
ANTHOPTILIDAE
PENNATULIDAE
FUNICULINIDAE
HALIPTERIDAE
KOPHOBELEMNIDAE
PROTOPTILIDAE
UMBELLULIDAE
VIRGULARIIDAE
ICES Advice 2013, Book 1
ACARNIDAE
Iophon piceum*
AXINELLIDAE
Axinella sp.*
Phakellia sp.*
ESPERIOPSIDAE
Esperiopsis villosa*
MYCALIDAE
Mycale (Mycale) lingua*
POLYMASTIDAE
Polymastia sp.*
Weberella bursa*
Weberella sp.
TETILLIDAE
Craniella cranium*
ROSELLIDAE
Asconema foliatum*
----ANTHOPTILIDAE
Anthoptilum grandiflorum
PENNATULIDAE
Pennatula aculeata*
Pennatula grandis
Pennatula sp.
FUNICULINIDAE
Funiculina quadrangularis*
HALIPTERIDAE
Halipteris cf. christii*
Halipteris finmarchica*
Halipteris sp.*
KOPHOBELEMNIDAE
Kophobelemnon stelliferum*
PROTOPTILIDAE
Distichoptilum gracile
Protoptilum sp.*
UMBELLULIDAE
Umbellula lindahli
VIRGULARIIDAE
Virgularia cf. mirabilis*
87
P ROPOSED NEAFC VME HABITAT
T YPE
5. Tube-dwelling anemone patches
R EPRESENTATIVE NEAFC
T AXA
CERIANTHIDAE
C ORRESPONDING NAFO SPECIES
6. Mud- and sand-emergent fauna
BOURGETCRINIDAE
BOURGETCRINIDAE
Conocrinus lofotensis
ANTEDONTIDAE
Trichometra cubensis
HYOCRINIDAE
Gephyrocrinus grimaldii
-----
ANTEDONTIDAE
HYOCRINIDAE
XENOPHYOPHORA
SYRINGAMMINIDAE
7. Bryzoan patches
-----
Pachycerianthus borealis*
EUCRATEIDAE
Eucratea loricata
* Species common to the NEAFC and the NAFO areas.
2) Maps of VME elements
ICES has mapped three areas with VME elements (geomorphological features likely to contain VMEs): the Mid-Atlantic
Ridge, the Rockall–Hatton area, and a set of isolated seamounts.
Mid-Atlantic Ridge
ICES advises that the Mid-Atlantic Ridge be regarded as one continuous combination of VME elements, southwards from
the boundary of the Icelandic EEZ to the boundary of the EEZ north of the Azores (Figure 1.5.5.3.1). It is a chain of
pinnacles, knolls, seamounts, ridges, and troughs that together make up one contiguous VME element. ICES has not
attempted to provide a boundary for the Mid-Atlantic Ridge.
88
ICES Advice 2013, Book 1
Figure 1.5.5.3.1
The extent of the Mid-Atlantic Ridge from the Azores in the south to Iceland in the north showing
peaks shallower than 2000 m depth. The NEAFC RA area is shown as a red boundary.
Rockall–Hatton area
ICES advises that the Rockall–Hatton area contains VME elements. These include some of the areas already closed to
fishing due to the certain presence of VMEs. ICES has mapped the following VME elements outside the currently
protected areas (Figure 1.5.5.3.2).
•
•
•
•
•
South Rockall Escarpment and Lorian Bank is an area of steep flanks, rising from 2000 m to the top of
Lorian Bank at a depth of 800 m.
Fangorn Bank is a knoll of very high rugosity, rising from 2000 m to around 1500 m.
Edora’s Bank Western Approach consists of two seamounts in this area known as the Eridor Seamounts,
both with summits above 2000 m and a steep flanked ridge running toward Edora’s Bank that is above
2000 m. A third seamount known as Rohan Seamount lies south of Edora’s Bank, with the summit at or just
below 2000 m.
The South Hatton Knoll has records of VME indicator species.
The southwest corner of Lousy Bank is the lower slope of a seamount.
ICES Advice 2013, Book 1
89
Figure 1.5.5.3.2
The Rockall–Hatton area, showing areas containing geomorphological features (black circles and
polygons) that can be considered VME elements at depths shallower than 2000 m (black contour)
that are currently open to bottom fisheries. Also shown are areas currently closed by NEAFC to
bottom fishing. Background multibeam bathymetry courtesy of Irish Geological Survey, Instituto
Español de Oceanografía (IEO) (Spain), and DTI (UK), with depth contours based on Gebco.
Isolated seamounts
ICES advises that all isolated seamounts (outside the Mid-Atlantic Ridge) whose summits are shallower than 2000 m
depth, be regarded as VME elements. Some of these seamounts might be grouped into broad areas (e.g. immediately SW
of the Azores EEZ), but equally they could be regarded as individual features (Figure 1.5.5.3.3).
90
ICES Advice 2013, Book 1
Figure 1.5.5.3.3
3)
Isolated seamounts outside the Mid-Atlantic Ridge with summits shallower than 2000 m depth. The
NEAFC RA area is shown as a red boundary.
Hydrothermal vents
There are only five known or inferred vent sites within the NEAFC RA (Figure 1.5.5.3.4). The vent sites, other than the
one inferred site on the Reykjanes Ridge, are deeper than 2000 m and are hence unlikely to be impacted by fishing
activities. The exact location of the site on the Reykjanes Ridge is not known, but due to the likely fragility of habitats
and organisms it is advised that all bottom-contacting fishing gear should be prohibited from the area.
ICES Advice 2013, Book 1
91
Figure 1.5.5.3.4
Confirmed or inferred hydrothermal vents in the North Atlantic. Three vents are clustered SW of
the Azores (circled). The NEAFC RA area is shown as a red boundary.
Background:
1) VME indicator species in the NEAFC and NAFO Regulatory Areas
FAO provides criteria for species indicative of VMEs. These are:
1)
2)
3)
4)
5)
unique or rare;
functionally significant;
fragile;
have unusual life-history traits, such as being long-lived, slow growing, late maturing, recruit unpredictably;
contribute to the structural complexity of the ecosystem.
NAFO’s list of taxa, used as indicators of VMEs in the Northwest Atlantic was drawn up by considering each of the
candidate VME indicator species in relation to the criteria outlined by the FAO guidelines.
It is important to appreciate that in the NEAFC RA, there are several biogeographic provinces, whereas the NAFO RA
consists of just one. A large number of taxa and some species are common to the NE and NW Atlantic (see Table
92
ICES Advice 2013, Book 1
1.5.5.3.1). For the most part, the families in both areas are comparable. There are some species and families that are not
on the NAFO list, but may represent VMEs in the NEAFC RA. These are cup corals, cauliflower coral gardens dominated
by soft corals of the family Nephtheidae, and fragile Xenophyophores. In the NAFO area there are species listed which
are not considered to be of relevance in the NEAFC RA, such as a species of sea lily (crinoid) in the family Hyocrinidae
that is currently unrecorded in NEAFC and bryozoan patches of the family Eucrateidae (Eucratea loricata), which only
occur in shallow waters.
2) VME elements
ICES applied NAFO’s VME element classification framework to features in the NEAFC RA. Table 1.5.5.3.2 lists five
VME elements (and the NAFO equivalent) identified by ICES that have a high likelihood of supporting VMEs. In some
cases there is evidence of VME indicators associated with these elements, but for other areas this cannot be verified at
the current time.
Table 1.5.5.3.2
List of VME elements known to occur in the NAFO and NEAFC Regulatory Areas (table modified
from NAFO SCS Doc 12/19, 2012).
P HYSICAL VME I NDICATOR E LEMENTS
Explanation
ICES/NEAFC
Examples from
Nomenclature
NEAFC RA
Isolated seamounts
Figure 1.5.5.3.2
Non-MAR
seamounts
NAFO Nomenclature
Examples from NAFO
RA
Seamounts
Fogo Seamounts
(Division 3O, 4Vs)
Newfoundland
Seamounts (Division
3MN)
Corner Rise Seamounts
(Division 6GH)
New England
Seamounts (Division
6EF)
Steep-slopes
and
peaks on mid-ocean
ridges
Mid-Atlantic
Ridge
(Figure 1.5.5.3.1)
Steep ridges and
peaks support
coral gardens and
other VME species
in high density
Not present
Knolls
Hatton Bank,
Fangorn Bank
(within
Figure 1.5.5.3.3)
A typographic
feature that rises
less than 1000 m
from the seafloor
Knolls
Orphan Knoll (Division
3K)
Beothuk Knoll
(Division 3 LMN)
Southeast Shoal Tail of
the Grand Bank
spawning grounds
(Division 3N)
Canyon-like features
Loury Canyon,
margin of
Edora’s Bank
(within
Figure 1.5.5.3.3)
A steep sided
‘catchment’
feature not
necessarily
associated with a
shelf, island or
bank margin
Canyons
Shelf-indenting canyon;
Tail of the Grand Bank
(Division 3N)
Canyons with head
>400 m depth; South of
Flemish Cap and Tail of
the Grand Bank
(Division 3MN)
Canyons with heads
>200 m depth; Tail of
the Grand Bank
(Division 3O)
Steep flanks >6.4º
SE Rockall
(within
Figure 1.5.5.3.3)
from NAFO SCR
Doc 11/73
Steep flanks >6.4º
South and southeast of
Flemish Cap. (Division
3 LM)
ICES Advice 2013, Book 1
93
Description of VME elements within the NEAFC Regulatory Area
i.
The Mid-Atlantic Ridge as one contiguous VME element
The Mid-Atlantic Ridge (MAR) between Iceland and the Azores may be characterised as one contiguous VME element
with a complex topography, comprising the axial valley and flanks with hills and valleys of various depths and
configurations and including many steep and seamount-like structures. Due to the structural complexity, mapping of
individual VME elements has not been attempted. It is likely that most features shallower than 2000 m on the MAR are
potential VME elements, but it should be noted that much of the area has a covering of sediment. Some major fracture
zones occur where the ridge axis is broken and include deep east–west steep-walled canyon-like troughs. The major
double fracture is the Charlie-Gibbs Fracture zone at about 52˚N.
ii.
VME elements in the Rockall–Hatton area
The Rockall–Hatton area is a topographically complex area that has numerous VME elements within it, including
seamounts, banks, steep flanks, and knolls shallower than 2000 m. Several of these have been previously identified by
ICES as sites of VMEs, e.g. the upper section of Hatton Bank, Edora’s Bank, and several areas in the northwest and
southwest of Rockall Bank. NEAFC has closed bottom fisheries in these areas. However, there are additional areas that
ICES has identified as containing VME elements (Figure 1.5.5.3.3). The Fangorn Bank has a single longline bycatch
record of black coral; there are no other records of VME indicator species from these additional areas.
iii.
Isolated seamounts (with summit shallower than 2000 m)
Seamounts by definition rise 1000 m or more from the surrounding seafloor. Isolated seamounts are distributed throughout
the NEAFC RA (Table 1.5.5.3.3).
94
ICES Advice 2013, Book 1
Table 1.5.5.3.3
L ATITUDE
( DECIMAL )
36.4246
36.0525
36.4796
35.989
36.4723
36.3057
36.4544
36.4507
36.4875
36.328
36.9826
36.6708
37.0739
37.0222
37.0316
37.0182
37.0541
43.4153
43.4194
43.59
44.7278
44.7219
44.4216
44.5803
44.9656
44.0997
45.1114
43.994
44.5156
44.5443
45.0443
44.6221
52.4838
56.0755
52.5106
59.9183
54.9042
54.5966
57.8537
54.8042
55.42
43.5762
43.574
43.5941
44.5381
43.4113
43.0192
44.1213
44.6749
43.0233
43.3909
41.3219
41.3236
43.971
43.5406
45.0787
43.7909
44.6842
44.0691
44.1033
Seamounts with summit shallower than 2000 m from the NEAFC area (from Morato et al., in press).
L ONGITUDE
( DECIMAL )
-33.8668
-33.7383
-33.8358
-33.6681
-33.7754
-34.3175
-33.4795
-33.378
-34.0619
-33.9304
-34.8651
-38.0743
-35.5123
-35.1158
-35.1771
-35.0318
-35.3837
-32.2388
-37.6799
-38.672
-34.3646
-34.0554
-40.2322
-33.9406
-40.9232
-38.9873
-39.4312
-36.5227
-40.4651
-40.5186
-40.9905
-40.9294
-41.0124
-37.3454
-40.5756
-34.1654
-25.285
-25.4485
-26.5802
-22.2819
-30.3948
-22.4496
-22.3927
-22.4984
-25.2685
-26.7975
-24.7639
-22.1207
-24.3592
-25.0386
-14.1022
-20.1974
-20.173
-21.7314
-22.2267
-13.4134
-22.9436
-25.4386
-21.8688
-21.9925
ICES Advice 2013, Book 1
S UMMIT DEPTH
(M)
434
802
936
968
985
1011
1098
1106
1131
1229
1717
1774
1869
1958
1968
1972
1986
895
943
1058
1240
1379
1491
1607
1729
1798
1855
1861
1885
1904
1940
1951
1558
1754
1823
1962
1533
1645
1681
1724
1842
958
961
993
1098
1124
1226
1231
1234
1297
1316
1407
1407
1529
1588
1682
1714
1747
1750
1798
H EIGHT
(M)
2036
1355
1507
1111
1483
1263
1281
1253
921
1342
984
1637
1110
1063
1095
970
1022
2601
2926
3194
2228
1716
2736
1612
2187
2321
2077
2084
2157
2108
1912
2216
1980
961
1714
976
1478
1081
1108
1623
1127
1952
2033
1971
1780
1942
2214
2169
1742
2072
3715
1947
1993
1832
1620
2506
1562
1150
1462
1330
B ASAL AREA
( KM 2 )
934
981
1111
1099
867
1119
783
841
449
488
1145
1088
914
792
878
560
688
841
1147
1413
1263
877
1584
999
1504
1161
1328
1074
1504
1408
1600
1252
1130
784
1372
698
1137
1264
883
1036
969
1568
1568
1600
1600
652
716
936
1274
979
988
1291
1303
1408
1472
1382
1317
1207
1363
965
95
41.4425
42.4846
43.6296
42.5894
41.9835
44.5478
43.5319
42.8153
44.2914
43.3793
41.5813
42.6668
36.7903
36.6345
36.8565
36.7007
36.669
37.0303
36.2319
36.304
36.6783
36.5771
37.5095
37.3402
-21.2099
-19.0334
-23.7155
-26.1673
-19.9793
-25.0516
-23.0083
-21.5212
-22.9451
-25.7231
-20.0606
-21.1705
-14.3063
-14.2357
-14.4412
-14.2756
-14.2468
-13.8794
-14.5563
-14.5609
-13.9654
-14.9466
-13.9323
-14.5041
1801
1801
1823
1859
1872
1888
1915
1981
1983
1985
1997
1999
120
153
162
188
192
846
925
1000
1197
1213
1335
1356
1713
2425
1256
1479
2052
941
1052
1371
1747
1048
1535
1532
1714
2251
1593
1915
2081
1830
2287
2026
2192
1263
2393
1567
1297
1520
1335
1029
1327
779
724
1365
1206
997
1309
1360
1328
1270
1600
1552
1221
1520
1199
1268
538
1424
1269
1477
37.4694
-14.137
1456
1721
1107
iv. Knolls
Knolls are topographic features that rise less than 1000 m from the surrounding seafloor. The resolution of standard
regional-scale bathymetric data does not allow a comprehensive analysis of this class of VME element.
v.
Canyon-like features
Most canyons in the ICES area are found along the European continental margins and there appears to be very few in the
NEAFC RA that are not part of the Mid-Atlantic Ridge or Rockall–Hatton area.
vi.
Steep flanks and slopes
Using bathymetric data, NAFO has classified areas of 6.4° or steeper slopes as VME elements (Murillo et al., 2011).
However, existing regional-scale bathymetric data are not resolved to a fine enough scale to make a comprehensive
analysis of this class of VME element.
3) Hydrothermal vents
In the NEAFC RA, hydrothermal vents occur on the Mid-Atlantic Ridge. While some have been visually surveyed and
studied, some remain unconfirmed and are inferred based on chemical plume detections in the overlying water column.
Three vent fields in the NEAFC RA are located southwest of the Azores, one lies north of the Azores, and one lies south
of Iceland on the Reykjanes Ridge (Figure 1.5.5.3.4 and Table 1.5.5.3.4). Only the vent on the Reykjanes Ridge is at a
depth shallower than 2000 m.
Table 1.5.5.3.4
Positions of known or inferred hydrothermal vents in the NEAFC RA.
A REA
V ENT NAME
Rainbow
L ATITUDE
( DECIMAL
36.21667
SW Azores
L ONGITUDE ( DECIMAL )
-33.9
SW Azores
AMAR
36.3833
-33.65
SW Azores
S AMAR 1
36.083
-34.083
North Azores
Moytirra
45.4833
-27.85
Reyjkanes Ridge
Reykjanes Ridge, Area A
62.45
-25.433
Measures to protect hydrothermal vents
96
ICES Advice 2013, Book 1
In 2010, a workshop sponsored by the International Seabed Authority (ISA) was held to formulate general guidelines for
the conservation of vent and seep ecosystems at regional and global scales. A number of anthropogenic pressures arising
from indirect commercial activities, such as shipping, cable laying, and waste disposal may impact upon seeps and vents.
The most severe threats to natural ecosystem structure and function at vents and seeps were considered to be the extractive
industries (minerals, hydrocarbons) and bottom trawl fisheries (International Seabed Authority, 2011).
Sources
ICES 2013. Report of the ICES/NAFO Joint Working Group on Deep-water Ecology (WGDEC). ICES CM 2013/ACOM:
28.
International Seabed Authority. 2011. Environmental Management of Deep-Sea Chemosynthetic Ecosystems:
Justification of and Considerations for a Spatially Based Approach. Available online at:
http://www.isa.org.jm/files/documents/EN/Pubs/TS9/index.html (accessed May 2013).
Morato, T., Kvile, K. Ø., Taranto, G. H., Tempera, F., Narayanaswamy, B. E.,. Hebbeln, D., Menezes, G., Wienberg, C.,
Santos, R. S., and. Pitcher, T. J. In press. Seamount physiography and biology in North-East Atlantic and
Mediterranean Sea. Biogeosciences.
Murillo, F. J., Kenchington, E., Sacau, M., Piper, D. J. W., Wareham, V., and Muñoz, A. 2011. New VME indicator
species (excluding corals and sponges) and some potential VME elements of the NAFO Regulatory Area. NAFO
SCR Doc. 11/73.
ICES Advice 2013, Book 1
97
1.5.5.4
ECOREGION
SUBJECT
Special request, Advice May 2013
General advice
Advice on threshold levels for longline fishing
Advice summary
ICES advises the use of a threshold of 10 VME indicators caught per 1000 hook segment or per 1200 m section of long
line, whichever is the shorter, to indicate the presence of a VME.
Request
ICES is requested to advice on the appropriateness of applying the threshold levels for VME indicator species for long
line fishing as adopted in the SEAFO, and CCMLAR, in the NEAFC RA.
ICES advice
ICES advises that NEAFC set specific threshold levels for VME indicator bycatch by longlines. This is because of the
substantial difference in the bycatch of VME indicators on longlines compared to trawls. ICES considers that the
application of threshold levels for VME indicators for longline fishing adopted by SEAFO and CCMLAR would be an
improvement on the current criteria to identify VMEs because it offers a way to standardize effort across fleets. However,
the application of the SEAFO and CCMLAR thresholds are complicated, rely upon 100% observer coverage and are
therefore unlikely to be operational in the NEAFC RA. ICES therefore advises to adapt the SEAFO and CCMLAR
thresholds and to use a threshold of 10 hooks with VME indicators per caught per 1000 hook segment or per 1200 m
section of long line, whichever is the shorter, to indicate the presence of a VME.
Background
Currently NEAFC operates a simple VME encounter measure for all fishing gear types including longlines, stating that
if over 30 kg of live corals or 400 kg of live sponges is taken as bycatch per set a VME is considered to have been
encountered and must be reported. This rule is considered inappropriate for long lines mainly because of the different
selectivity of long lines compared to trawls and because of the heterogeneity of the long line fleet in the NEAFC RA. The
long line fisheries in the NEAFC RA vary considerably according to target species, characteristics of the fishing areas
and traditions, ranging from technically advanced and highly mechanized fisheries on large vessels to small-scale
traditional artisanal fisheries. The differentiation also includes variability in the number of hooks.
SEAFO and CCMLAR consider a ‘VME indicator unit’ either one litre of the type of VME indicator organisms that can
be placed in a 10-litre container, or one kilogramme of the type of VME indicator organisms that do not fit into a 10-litre
container. The threshold is exceeded when 10 or more VME indicator units are collected per 1000 hook segment or a
1200 m section of line, whichever is the shorter.
Sources
CCAMLR. 2010. http://www.ccamlr.org/en/measure-22-07-2010.
ICES. 2013. Report of the ICES/NAFO Joint Working Group on Deep-water Ecology (WGDEC). ICES CM
2013/ACOM: 28.
SEAFO. 2011.
http://www.seafo.org/ConservationMeasures/Conservation%20Measure%202211%20on%20Bottom%20Fishing%
20Activities%20in%20the%20SEAFO%20Convention%20Area.pdf.
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ICES Advice 2013, Book 1
1.5.5.5
Special request, Advice June 2013
ECOREGION
SUBJECT
General advice
OSPAR/NEAFC special request on review of the results of the Joint
OSPAR/NEAFC/CBD Workshop on Ecologically and Biologically
Significant Areas (EBSAs)
Advice summary
ICES reviewed the ecological evidence supporting the ten proposed ecologically and biologically significant areas
(EBSAs) from the OSPAR/NEAFC/CBD Workshop of September 2011, as presented in the annexes to that report. The
review applied standard ICES practices and used primarily the references cited in the relevant annexes, but augmented
those references with other publications and data sources. In nine of the ten proposed EBSAs, ICES came to different
conclusions than were contained in the OSPAR/NEAFC/CBD Workshop report, with regard to the rankings of the
Convention on Biological Diversity (CBD) EBSA criteria.
Of the ten proposed EBSAs, ICES supports the conclusion of the OSPAR/NEAFC/CBD workshop that the Arctic Ice
area (Area 10) meets one or more EBSA criteria and this area could go forward at this time, possibly with minor suggested
changes to the rationale.
In four proposed EBSAs (Reykjanes Ridge south of Iceland EEZ (Area 1); Charlie-Gibbs Fracture Zone and Subpolar
Frontal Zone of the Mid-Atlantic Ridge (Area 2); Mid-Atlantic Ridge north of the Azores (Area 3); the Hatton and Rockall
banks and Hatton–Rockall Basin (Area 4)), ICES considers that much of the area within the proposed EBSAs do not meet
any of the EBSA criteria and for this reason the boundaries of these proposals need to be revised. More restricted parts of
the proposed EBSAs meet several of the EBSA criteria and could go forward after boundary revision. ICES notes great
similarities in the pro forma describing Areas 1 and 3 and part of Area 2 (OSPAR/NEAFC/CBD, 2011). A boundary
revision to encompass the relevant parts of these areas as a single extended Mid-Atlantic Ridge proposed EBSA could be
considered a step forwards. ICES recommends changes also to the pro forma rankings for all of these proposed EBSAs.
Only a small part of the proposed EBSA for the Arctic Front – Greenland/Norwegian seas (Area 9) possibly meets some
of the EBSA criteria. However, another part of the general area might meet some of the EBSA criteria. ICES recommends
that further data analyses followed by an evaluation of the new results against the EBSA criteria be undertaken before
any further decision is taken.
The rationales for four proposed EBSAs (around the Pedro Nunes and Hugo de Lacerda seamounts (Area 5); Northeast
Azores–Biscay Rise (Area 6); Evlanov Seamount region (Area 7); and Northwest of Azores EEZ (Area 8)) are not well
supported by the information presented in the relevant annexes. There is a need for further data and analyses in these
areas, particularly in relation to seabirds, and another evaluation of the areas against the EBSA criteria.
ICES found no clear evidence of additional EBSAs in areas beyond national jurisdiction (ABNJ) of the Northeast Atlantic
meeting the CBD scientific criteria.
Request
a) Review the description of areas meeting one or more of the CBD EBSA scientific criteria developed as an outcome of
the Joint OSPAR/NEAFC/CBD Scientific Workshop, in particular:
1. Review each of the ten area delineations and descriptions in line with the CBD EBSA Scientific criteria and
the most up-to-date scientific data and information, specifying any additional scientific data and information
that is available;
2. Provide, if appropriate, revised EBSA proposals in the format of proformas adopted by the CBD
b) If there is clear evidence for additional areas in ABNJ of the North-East Atlantic meeting the CBD EBSA scientific
criteria, present a description with supporting scientific data and information for such areas, including CBD EBSA
proformas for each.
ICES advice
ICES made the following conclusions and proposals.
ICES Advice 2013, Book 1
99
Area 1. Reykjanes Ridge south of Iceland EEZ: Much of the area in the proposed EBSA does not meet any of the EBSA
criteria. A more restricted area down the spine of the Mid-Atlantic Ridge and defined by depth ranges of deep-water coral
and sponge concentrations does meet several EBSA criteria and the boundary delineation, ranking, and full rationale
could be developed based on this new boundary.
Area 2. Charlie-Gibbs Fracture Zone and Subpolar Frontal Zone of the Mid-Atlantic Ridge: Some areas in the proposed
EBSA do not meet any of the EBSA criteria. A complex combination of the area down the spine of the Mid-Atlantic
Ridge, the benthic area aligned with and close to the main fractures, and the water column in which the Subpolar Front is
found throughout the year, does meet several EBSA criteria and the boundary delineation, ranking and full rationale could
be developed at based on this new boundary.
Area 3. Mid-Atlantic Ridge north of the Azores: Much of the area in the proposed EBSA does not meet any of the EBSA
criteria. A more restricted area down the spine of the Mid-Atlantic Ridge and defined by depth ranges of deep-water coral
and sponge concentrations does meet several EBSA criteria and the boundary delineation, ranking, and full rationale
could be developed based on this new boundary.
Area 4. The Hatton and Rockall banks and Hatton–Rockall Basin: Much of the area in the proposed EBSA does not meet
any of the EBSA criteria. A more restricted area down to approximately 1500–1800 m depth, but excluding the abyssal
plain does meet several EBSA criteria and the boundary delineation, ranking, and full rationale could be developed based
on this new boundary.
Area 5. Around the Pedro Nunes and Hugo de Lacerda seamounts: The proposed EBSA is not supported well by the
information presented in the pro forma. There is a need for further analyses of those data already considered, as well as
any additional relevant data on seabird foraging and other information. When these analyses are done, including for the
additional data, another evaluation of the area against the CBD EBSA criteria would make it possible to advise which
areas, if any, meet EBSA criteria.
Area 6. Northeast Azores–Biscay Rise: The proposed EBSA is not supported well by the information presented in the pro
forma. There is a need for further analyses of those data already considered as well as any additional relevant data on
seabird foraging and other information. When these analyses are done, including for the additional data, another
evaluation of the area against the CBD EBSA criteria would make it possible to advise which areas, if any, meet EBSA
criteria.
Area 7. Evlanov Seamount region: The proposed EBSA is not supported well by the information presented in the pro
forma. There is a need for further analyses of those data already considered as well as any additional relevant data on
seabird foraging and other information. When these analyses are done, including for the additional data, another
evaluation of the area against the CBD EBSA criteria would make it possible to advise which areas, if any, meet EBSA
criteria.
Area 8. Northwest of Azores EEZ: The proposed EBSA is not supported well by the information presented in the pro
forma. There is a need for further analyses of those data already considered as well as any additional relevant data on
seabird foraging and other information. When these analyses are done, including for the additional data, another
evaluation of the area against the CBD EBSA criteria would make it possible to advise which areas, if any, meet EBSA
criteria.
Area 9. The Arctic Front – Greenland/Norwegian seas: Only a small part of the area proposed by the
OSPAR/NEAFC/CBD Workshop as an EBSA was considered to possibly meet some of the criteria. However, another
part of the general area might meet some EBSA criteria. There is a need for more analyses of productivity and diversity
data for the more southerly part of the main area, and then a re-evaluation of the new results against the EBSA criteria,
before any areas might be considered as possibly meeting EBSA criteria.
Area 10. The Arctic Ice: The rationale for concluding that this area meets one or more EBSA criteria can be improved,
but the review by ICES generally supports the conclusions of the OSPAR/NEAFC/CBD workshop. A suggested revised
proforma is attached as Annex 1.5.6.5.1 to this advice.
With regard to new proposed areas that meet EBSA criteria, ICES has no additional information. However, ICES suggests
a potential alternative configuration to the areas in proposed EBSAs 1, 2, and 3 that would comprise two areas meeting
EBSA criteria, one covering the specified depths of the entire Mid-Atlantic Ridge, and one for the Charlie-Gibbs Fracture
Zone and pelagic area of the Subpolar Front. Each of the two areas would have coherent, but different ecological
rationales.
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ICES has provided its rankings for the revised proposed EBSAs and the rationale for those rankings. ICES has not revised
the narrative or the references in the existing pro forma of proposed EBSAs other than for Arctic Ice habitat (Annex
1.5.6.5.1). Once OSPAR and NEAFC have made a decision on the configuration of the Mid-Atlantic Ridge proposed
EBSAs, ICES could revise the pro forma for these EBSAs by the end of September 2013.
Background
Method
ICES conducted its review informed by the content of the CBD Decisions IX/20 and X/29 on Marine and Coastal
Biodiversity (CBD, 2008, 2010), the reports from the ‘Azores Workshop’ (CBD, 2007) and the ‘Ottawa Workshop’
(CBD, 2009), and the UNGA Resolution 58/240 (United Nations, 2004). ICES considers that the application of the criteria
was intended to be a comparative or relative process, such that areas should be evaluated against other generally
comparable areas (e.g. of comparable depth and latitude). In addition, even though the application of EBSA criteria is not
guided directly by management considerations, potential benefits of spatial management measures are a relevant
consideration in the evaluation. However, the appropriate baseline is not the absence of all management, but the presence
of measures sufficient to ensure human uses are sustainable in areas typical of the zone of evaluation.
ICES is responding to a request about EBSAs, and ICES stresses that this advice does not imply that any areas reviewed
should or should not be considered as VMEs (but ICES notes that there is an overlap with advice provided recently on
vulnerable marine ecosystems (VMEs; ICES, 2013a)). ICES notes that all areas found to meet criteria for VMEs would
be expected to meet one or more criteria for EBSAs as well. However, the reverse is not necessarily true and EBSAs do
not necessarily contain VMEs. There is neither a policy nor an ecological rationale for automatically excluding bottom
fishing (or any other activity) from areas proposed as EBSAs. The expected initial response of regulatory authorities is to
conduct risk or threat assessments of the activities they regulate relative to the properties considered ecologically or
biologically significant, and to subsequently undertake management appropriate to the outcome of these assessments.
ICES advice is based on applying several standards during its review, including:
•
•
•
•
•
Assigned rankings on a criterion should apply to at least most of the area included in a proposed EBSA, and not just
to a small subset of the total area.
Higher assigned rankings required the proposed area to differ from adjacent areas and other areas of similar depth
and latitude on the property represented by the criterion.
Some evidence must be available to justify awarding a higher ranking, noting that comprehensive data for the high
seas cannot be expected.
Rankings should not be based on the presence or history of threats to the features represented by the criteria, but on
the biological, ecological, and geomorphological features of the area.
Although EBSAs are not defined by or linked to any particular management actions by any authorities, it is
appropriate to consider whether or not spatial management tools might benefit the conservation or sustainable use of
the relevant features.
For each of the ten areas in the OSPAR/NEAFC/CBD report proposed to meet EBSA criteria, ICES assigned one of three
categories:
•
•
Proceed with boundaries proposed by the OSPAR/NEAFC/CBD Workshop, with a rationale revised by ICES.
Proceed with developing a proposed EBSA with different boundaries than those proposed by the
OSPAR/NEAFC/CBD Workshop, and with a rationale provided by ICES.
• Do not proceed with proposing an EBSA at this time, but rather undertake further collation and analysis of
information and reconsider when the additional work is completed.
Although ICES review included an evaluation and commentary on all pro forma contents of the OSPAR/NEAFC/CBD
2011 Workshop report, this advice presents only ICES conclusions as to whether the areas meet the EBSA criteria. This
advice takes the form of biological properties that ICES concludes would define the boundaries, rankings, and rationales
of those areas against the EBSA criteria.
Proposed EBSAs that need minor revisions to the rationale
Area 10. The Arctic Ice
A suggested revised pro forma is attached to this advice as Annex 1.5.6.5.1.
Proposed EBSAs that should have redefined boundaries before proceeding
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101
Area 1. Reykjanes Ridge south of Iceland EEZ
ICES advises that an area along the Reykjanes Ridge can be justified as meeting one or more EBSA criteria. This would
be a much smaller area than the one proposed in the OSPAR/NEAFC/CBD Workshop report. Appropriate boundaries for
such a proposed area that meets EBSA criteria would be a depth contour that runs in the deeper of two properties:
1.
2.
Including a large portion (arbitrarily, perhaps 90%) of all hard volcanic substrates; habitats are reported to host
the larger known coral formations and their associated communities
Including a large portion (arbitrarily, 90%) of the records of large sponge communities in the overall northern
Mid-Atlantic Ridge.
In addition, the proposed area will include the only known hydrothermal vent in the area (Olafsson et al., 1991; German
et al., 1994; German and Parsons, 1998; Mironov and Gebruk, 2007), whatever depth contour is used. Information on
water masses should also be consulted, allowing proper identification of benthic and fish fauna to be included in a revised
narrative to a pro forma for this area.
In the time available ICES did not have the geological data to delineate the depth contour that would meet the first
criterion, but such information should be readily available in marine geology databases. Nor did ICES have access to all
of the records of where the large sponge deposits were taken. However, references to sources for those data are in the
OSPAR/NEAFC/CBD Workshop pro forma and should be tracked back to find the appropriate depth contour for the
second criterion in the tables below.
Evaluation of the revised area against the EBSA criteria
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Know
The area contains either (i) unique
(“the only one of its kind”), rare
(occurs only in few locations), or
endemic species, populations, or
communities, and/or (ii) unique,
rare, or distinct habitats or
ecosystems, and/or (iii) unique or
unusual
geomorphological
or
oceanographic features.
Explanation for ranking
Uniqueness
rarity
or
Low
Some
High
X
(X)
The bracketed “High” ranking is for a very restricted area covering the only known hydrothermal vent on the Reykjanes
Ridge. Though this is a unique feature it occupies only a small part of the area proposed here as meeting this EBSA
criterion (Olafsson et al., 1991; German et al., 1994; German and Parsons, 1998; Mironov and Gebruk, 2006).
The MarEco sampling of corals and sponges reported a few species new to science and these may be restricted to the
proposed area, although a firm conclusion on this cannot be drawn until more extensive sampling is undertaken.
Areas that are required for a
Special
X
importance for population to survive and thrive.
life-history
stages of species
Explanation for ranking
Although many populations undoubtedly complete their life cycles within the large area proposed in the
OSPAR/NEAFC/CBD Workshop Report as an EBSA, this would be true of any marine area of comparable size. There
is no evidence that the life history of any species is strongly dependent on any specific features of the area proposed
as an EBSA.
There is evidence from other areas of the Northeast Atlantic that areas of high coral density may be important as eggcase and nursery areas of deep-water sharks and rays. The area proposed here is targeted on the depths and substrates
associated with higher coral and sponge densities, and if sharks and rays also concentrate spawning and early
development in these habitats, then the score would be “Some” or “High” on this criterion as well.
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CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Know
Areas containing habitats for the
survival
and
recovery
of
endangered,
threatened,
or
declining species, or areas with
significant assemblages of such
species.
Explanation for ranking
Importance for
threatened,
endangered, or
declining species
and/or habitats
Low
Some
High
X
Large formations of corals and sponges are found in the area proposed by ICES as meeting this criterion. Habitats
containing these species are listed by OSPAR and also feature as VME indicator species; the majority of these would
be included in the proposed EBSA. Additional explanation regarding corals and sponges is included in the rationale
for the criterion on Vulnerability.
The possible role of the area proposed by ICES in the life histories of sharks and rays is discussed in the criterion on
Vulnerability and Sensitivity.
Areas that contain a relatively high
Vulnerability,
X
proportion of sensitive habitats,
fragility,
sensitivity,
or biotopes, or species that are
functionally
fragile
(highly
slow recovery
susceptible to degradation or
depletion by human activity or by
natural events) or with slow
recovery.
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CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Know
Low
Some
High
Explanation for ranking
With regard to corals and sponges, Mortensen et al. (2008) found cold-water corals “at every sample station …
observed at depths between 800 and 2400 m, however were commonly found shallower than 1400 m …, with species
richness being very high. … no major reef structures were recorded, with the maximum colony size approximately 0.5
m in diameter. The number of coral taxa was strongly correlated with the percentage cover of hard bottom substrate
….” The area proposed here is targeted at the seamount peaks and slopes where hard substrates dominate. For sponges,
no actual large expanses of sponge reef were reported in the OSPAR/NEAFC/CBD Workshop report. However, the
pro forma in that report (OSPAR/NEAFC/CBD, 2011) notes that overall sampling of the area is patchy and cites three
studies that found local patches with high densities of sponges, although in no cases were the sizes of the patches
documented.
These observations of widespread occurrences of corals and sponges are supported by the records in the GRID–Arendal
data, which show both taxa to be presented in nearly every appropriate sample taken along the cruise tracks in the
database.
Biological
productivity
Areas containing species,
populations, or communities
with comparatively higher
natural biological productivity.
X
Explanation for ranking
Although benthic productivity of the proposed smaller EBSA may be higher than benthic productivity on the abyssal
plain, productivity integrated over the entire water column and seafloor seems typical of systems of comparable depth
and latitude globally.
Areas
containing
a
Biological diversity
X
comparatively higher diversity
of
ecosystems,
habitats,
communities, or species, or
with higher genetic diversity.
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CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Know
Low
Some
High
Explanation for ranking
The possible, but incompletely documented presence of large coral and sponge stands, and the documented high
diversity of benthic and associated fish when corals or sponges are present in moderate or high density imply that some
areas may have high diversity. Aside from these benthic communities of somewhat restricted distribution, the
biodiversity otherwise appears typical of biotic communities at similar depths and latitude.
Area 2. Charlie-Gibbs Fracture Zone and Subpolar Frontal Zone of the Mid-Atlantic Ridge
ICES advises that an area with the following boundaries, capturing three distinct features, would meet one or more EBSA
criteria. The area would include the following features:
i.
ii.
iii.
Subpolar Frontal Zone (coinciding with the Charlie-Gibbs Fracture Zone): The northern and southern
boundaries for this feature should be set according to the known northernmost and southernmost meandering of
the frontal system at 53°N and 48°N, respectively (Søiland et al., 2008). The eastern and western boundaries for
this feature should be set according to the eastern and westernmost extension of the Charlie-Gibbs Fracture Zone
(topography; approx. at 27°W and 42°W, respectively).
Charlie-Gibbs Fracture Zone: The eastern and western boundaries for this feature should be set according to the
east–west extension of the Fracture Zone (approx. at 27°W and 42°W, respectively). The northern and southern
boundaries for this feature should be set with a view to encompass the characteristic bathymetry, topography,
and substrates of the Fracture Zone.
Sections of the Mid-Atlantic Ridge: The northernmost and southernmost boundaries would coincide respectively
with the southern boundary of proposed Area 1 (Reykjanes Ridge south of Iceland EEZ) and the northern
boundary of proposed Area 3 (Mid-Atlantic Ridge north of the Azores). Boundaries to the east and to the west
would be a depth contour running in the deeper of two properties:
•
•
including a large portion (arbitrarily, perhaps 90%) of all hard volcanic substrates; habitats reported to
host the larger known coral deposits and their associated communities;
including a large portion (arbitrarily, 90%) of the larger known deep-sea sponge aggregations.
Where the Charlie-Gibbs Fracture Zone crosses the Mid-Atlantic Ridge, the benthic boundaries of the Fracture Zone in
feature ii) may extend to the east and west beyond the area defined by feature iii) for the Mid-Atlantic Ridge. In those
cases the benthic area of the Fracture Zone is proposed for inclusion in the EBSA proposed here. However, any part of
the seafloor and associated benthos that lies below the pelagic feature i) (the total area occupied by the Subpolar Front
during its annual movement) but does not meet either feature ii) or feature iii) is not included in the area proposed as
meeting EBSA criteria. Only those parts of the water column where the Subpolar Front is prominent at some time during
the year are proposed as meeting one or more of the EBSA criteria. Moreover, in the entire pelagic area described by i),
at any given time only those parts of the total area where the Subpolar Front is located would be expected to meet some
of the criteria. Although maps will show the full pelagic area is proposed as part of this complex EBSA, any conservation
measures for ecological properties of the water column would need to take into account the position of the Subpolar Front
to be fully effective. For each of the above-mentioned features a set of geographic coordinates delineating their respective
boundaries needs to be determined.
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105
Evaluation of the revised area against the EBSA criteria
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t Know
The area contains either (i) unique
(“the only one of its kind”), rare
(occurs only in few locations), or
endemic species, populations, or
communities, and/or (ii) unique,
rare, or distinct habitats or
ecosystems, and/or (iii) unique or
unusual
geomorphological
or
oceanographic features.
Explanation for ranking
Uniqueness
rarity
or
Low
Some
X
High
(X)
The portion of the proposed area encompassing both the Charlie-Gibbs Fracture Zone and Subpolar Front Zone are
unique. Both represent unique or unusual geomorphological or oceanographic features in the Northeast Atlantic. Other
portions of the proposed EBSA are part of the Mid-Atlantic Ridge and, as discussed for Area 1 (Reykjanes Ridge south
of Iceland EEZ), may host some unique benthic species based on Mar-Eco sampling.
Areas that are required for a
Special
X
importance for population to survive and thrive.
life-history
stages of species
Explanation for ranking
There is no evidence available suggesting a significant importance of the area for life-history stages of widespread
species in comparison to other marine areas of similar size and depth range.
Importance for Areas containing habitats for the
X
survival
and
recovery
of
threatened,
endangered, or endangered, threatened, or declining
species, or areas with significant
declining
species and/or assemblages of such species.
habitats
Explanation for ranking
There is good evidence that the area contains a significant assemblage of species and habitats that are assessed to be
threatened, endangered, or declining, including the following: orange roughy (Hoplostethus atlanticus), leafscale
gulper shark (Centrophorus squamosus), gulper shark (Centrophorus granulosus), Portuguese dogfish (Centroscymnus
coelepis), Sei whale (Balaenoptera borealis), sperm whale (Physeter macrocephalus), leatherback turtle (Dermochelys
coriacea), Lophelia pertusa reefs, and deep-sea sponge aggregations. Depending on the species, the special features
of the Fracture Zone, the Subpolar Frontal Zone, or in a few cases the Mid-Atlantic Ridge, all provide important
biological functions to the species which aggregate along each one.
Areas that contain a relatively high
Vulnerability,
X
proportion of sensitive habitats,
fragility,
sensitivity, or biotopes, or species that are
functionally
fragile
(highly
slow recovery
susceptible to degradation or
depletion by human activity or by
natural events) or with slow
recovery.
Explanation for ranking
The Charlie-Gibbs Fracture Zone and sections of the Mid-Atlantic Ridge through its associated substrate, current, and
feeding conditions, provide habitats to a number of sensitive/vulnerable species and communities both on soft and hard
substrate and in the water column. In particular biogenic habitats such as those formed by cold-water corals and sponges
are considered vulnerable, often fragile, and slow (if at all) to recover from damage. Some fish species associated with
the Fracture Zone and Mid-Atlantic Ridge also show slow growth, late maturity, irregular reproduction, and long
generation time, as well as community characteristics of high diversity at low biomass. However, there is no evidence
available suggesting that the area contains a significantly higher proportion of species that are functionally fragile or
with slow recovery than other areas of comparable structure and depth range along the Mid-Atlantic Ridge.
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CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t Know
Areas
containing
species,
populations, or communities with
comparatively
higher
natural
biological productivity.
Explanation for ranking
Biological
productivity
Low
X
Some
High
(X)
There is good evidence that, due to the Subpolar Front, the pelagic area where the front is located at any particular time
is characterized by an elevated abundance and diversity of many taxa, including an elevated standing stock of
phytoplankton. This justifies a ranking of “High” for the pelagic area around the Subpolar Front, as it moves seasonally.
However, there is no evidence of relatively elevated productivity in the benthic communities of the Fracture Zone and
Mid-Atlantic Ridge.
Areas containing a comparatively
Biological
X
(X)
higher diversity of ecosystems,
diversity
habitats, communities, or species, or
with higher genetic diversity.
Explanation for ranking
The area of the Fracture Zone is characterized by a very high structural complexity, offering a diverse range of habitats.
The area of the Subpolar Front is a feature where species are documented to assemble seasonally, and the sections of
the Mid-Atlantic Ridge north and south of the Fracture Zone represent different biogeographic settings and their
respective characteristic communities. Consequently, each of the three features characterizing this area contribute to a
relatively higher diversity of ecosystems, habitats, communities, and species in comparison to other areas of similar
size along the Mid-Atlantic Ridge.
Area 3. Mid-Atlantic Ridge north of the Azores
ICES considers that one or more EBSA criteria would be met by an area with boundaries including all the following
properties:
•
•
•
Including a large portion (arbitrarily, perhaps 90%) of all hard volcanic substrates on the Mid-Atlantic Ridge
south of the summer location of the Subpolar Front.
Including the Moytirra Hydrothermal Vent Field.
Incluings the area in the Mid-Atlantic Ridge included in the 50% density Kernel for foraging Cory’s shearwater.
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107
Evaluation of the proposed area against the EBSA criteria
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Know
The area contains either (i) unique
(“the only one of its kind”), rare
(occurs only in few locations), or
endemic species, populations, or
communities, and/or (ii) unique,
rare, or distinct habitats or
ecosystems, and/or (iii) unique or
unusual
geomorphological
or
oceanographic features.
Explanation for ranking
Uniqueness
rarity
or
Low
X
Some
High
(X)
There is support for qualification under this criterion only from the hydrothermal vent field in the area which is
considered to be rare, and its associated communities which may be unique. This habitat is known from a single discrete
location (thus the brackets) and so it cannot be considered to offer justification for the entire extent of the proposed
area. ICES does not consider that any of the other evidence presented here supports qualification under this criterion.
Areas that are required for a
Special
X
importance for population to survive and thrive.
life-history
stages of species
Explanation for ranking
There is some support for qualification under this criterion from the occurrence of an important long-range foraging
area for Cory’s shearwaters during their breeding season. However, the core area encompassing 50% of locations at
sea is relatively small and does not justify the entire extent of the proposed area.
If research finds that deep-sea sharks and rays use the denser coral deposits as important spawning and nursery grounds,
as has been reported in the Hatton–Rockall Bank area proposed by ICES, then there would be additional justification
for a score of “Some” on this criterion.
Importance for Areas containing habitats for the survival and
X
recovery of endangered, threatened, or declining
threatened,
endangered, or species, or areas with significant assemblages of
such species.
declining
species and/or
habitats
Explanation for ranking
The only recognised threatened and/or declining species identified in the report as occurring in the area are the deepwater sharks Centrophorus squamosus and Centroscymnus coelolepis, both of which are included on the OSPAR list
of threatened and/or declining species and habitats. Since this area is not considered to have special importance for
their survival (compared with other areas of similar depth and latitude elsewhere) they would not qualify under this
criterion.
However, in addition to the threatened and declining species mentioned in the proposal, the OSPAR listed habitats
‘seamount communities’ and ‘coral gardens’ are likely to exist in this area. If these were taken into account together
with the sharks, this might be regarded as a significant assemblage of threatened and declining species and habitats
and the ranking would be “Some”.
Areas that contain a relatively high proportion of
Vulnerability,
X
sensitive habitats, biotopes, or species that are
fragility,
sensitivity, or functionally fragile (highly susceptible to
degradation or depletion by human activity or by
slow recovery
natural events) or with slow recovery.
Explanation for ranking
The proposed area focuses on areas with high abundance of seamounts, stony corals, and coral gardens. Recently a
new hydrothermal vent was discovered on the ridge at 45ºN. Seamounts, ocean ridges with hydrothermal vents, coral
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CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
High
Know
reefs, and coral gardens are all considered priority habitats in need of protection by the OSPAR convention for the
protection and conservation of the Northeast Atlantic.
There is good support for qualification under this criterion from the occurrence of vulnerable marine ecosystems,
including seamounts, stony corals, coral gardens, and hydrothermal vents.
Areas containing species, populations, or
Biological
X
communities with comparatively higher natural
productivity
biological productivity.
Explanation for ranking
There is no evidence that the productivity in the revised area is any different from the expected productivity of marine
systems of similar depth and latitude.
Areas containing a comparatively higher diversity of
Biological
X
ecosystems, habitats, communities, or species, or
diversity
with higher genetic diversity.
Explanation for ranking
The presence of a hydrothermal vent field does not in itself indicate high diversity, but it does provide some evidence
of habitat heterogeneity from which species diversity may be inferred. In addition, there is a mingling of benthic
faunas characteristic of both warmer southern and cooler northern ocean environments, giving the area as a whole
somewhat higher net biological diversity, although the diversity in any individual site is not markedly enhanced.
Area 4. The Hatton and Rockall banks and the Hatton–Rockall Basin
The Hatton and Rockall banks, and associated slopes, represent unique offshore bathyal habitats (200 to 3000 m) and
constitute a prominent feature of the Northeast Atlantic continental margin south of the Greenland to Scotland ridges.
The banks and slopes have high habitat heterogeneity and support a wide range of benthic and pelagic faunas. They are
also subject to significant fishing impact, including bottom trawling, longlining, and midwater fisheries. The banks
encompass a large depth range and consequently the seabed communities encounter strong environmental gradients (e.g.
temperature, pressure, and food availability). These factors cause large-scale changes in species composition with depth
and give rise to a high diversity of species and habitats. The area is influenced by a number of different water masses and
there is considerable interaction between the topography and physical oceanographic processes, in some areas focusing
internal wave and tidal energy which results in strong currents and greater mixing and resuspension.
ICES recommend that additional work is needed primarily to refine the boundaries set out for this proposed EBSA. In
particular the evidence base to use the 3000 m contour as the southern and western limits of this proposed EBSA is
questionable since no evidence was provided that ecosystems meeting EBSA criteria are present at these depths. The
features contributing to the uniqueness and rarity, threatened and declining species, vulnerability/fragility/sensitivity, and
importance for life-history criteria stages all occur exclusively at relatively shallow depths (< 1500 m) with most being <
1200 m, and the only additional benefit gained by extending the boundary to 3000 m is an increase in the overall depth
range covered and hence additional biological diversity. It is unclear whether the additional diversity conferred by the
inclusion of the 1500 to 3000 m depth zone is any different from that present in any other area at comparable depth and
latitude.
ICES therefore recommends that proposed EBSA should go forward with a revised boundary approximating to the 1500
m depth contour. If further work can establish significant additional value in the inclusion of greater depths, the boundary
could be adjusted accordingly in the future.
Evaluation of the proposed area against the EBSA criteria
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Know
Uniqueness
rarity
or
The area contains either (i) unique (“the only one
of its kind”), rare (occurs only in few locations), or
endemic species, populations, or communities,
ICES Advice 2013, Book 1
Low
Some
High
X
(X)
109
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Know
Low
Some
High
and/or (ii) unique, rare, or distinct habitats or
ecosystems, and/or (iii) unique or unusual
geomorphological or oceanographic features.
Explanation for ranking
The area has considerable environmental heterogeneity, and therefore biological diversity, as a result of its large depth
range and strong environmental gradients. Habitat-forming sessile benthic communities, such as those of giant
protozoans and sponges, are common. Although distinctive these features are not rare per se.
Large areas of cold-water corals and sponges have been reported in the area. Some of these have been impacted by
bottom trawl and longline fishing and past periods of bottom gillnet fishing, but some areas of large coral frameworks
still exist, including areas such as the Logachev coral carbonate mound province which spans both national EEZ
(Ireland) and international waters. Many of these coral frameworks are now protected as VMEs.
An area of polygonal faults may be a unique seabed feature. It is currently poorly investigated but may host important
biological communities (e.g. cold-seeps).
The polygonal faults do not themselves appear to support unique biological communities or species but may be
indicative of possible presence of active hydrocarbon seeps. One such active seep has recently been discovered in this
area, supporting a rare chemosynthetic community that hosts species that have not been recorded elsewhere (hence the
bracketed “High” score).
There is support for qualification under this criterion from the occurrence of polygonal faults and an active cold
hydrocarbon seep. These features exist within a very restricted area of the site and, as described, the uniqueness and
rarity criterion would only apply where these habitats occur. If further information is provided on the occurrence of
large areas of cold-water coral reef, this may provide further support for this criterion over a wider geographical area.
Areas that are required for a population to survive
Special
X
importance for and thrive.
life-history
stages of species
Explanation for ranking
Cold-water corals and areas of natural coral rubble provide highly diverse habitats. Recent observations show that
Lophelia pertusa reefs provide nursery grounds for deep-water sharks, and egg cases of deep-water rays were recorded
with small patches of Solenosmilia variabilis framework on the Hebrides Terrace Seamount during the RRS James
Cook 073 Changing Oceans Expedition in June 2012. New evidence from RRS James Cook cruises 073 and 060 shows
that small patch reefs of L. pertusa on Rockall Bank are used as refuge by gravid Sebastes viviparous.
Parts of the Hatton–Rockall area are important as spawning areas for blue whiting, and the area is used as a corridor
for a range of migrating species, including turtles.
Blue whiting has a widespread spawning area from the Faroe–Shetland Channel in the north to the Porcupine Bank in
the south. Three areas of blue ling spawning aggregations are known on the shallow parts of Hatton and Lousy banks.
These are significant since they represent three of the six known or suspected spawning locations for the southern stock
of blue ling.
Importance for Areas containing habitats for the survival and
X
recovery of endangered, threatened, or declining
threatened,
endangered, or species, or areas with significant assemblages of
such species.
declining
species and/or
habitats
Explanation for ranking
The OSPAR threatened and declining habitats and species “carbonate mounds” and Lophelia pertusa are confirmed to
be present in the area, and indicator species for “deep-sea sponge aggregations” and “coral gardens” have been recorded.
The presence of these habitats has been confirmed in some areas that are now protected as VMEs.
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ICES Advice 2013, Book 1
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
High
Know
The cold-water corals and natural rubble contain very large numbers of invertebrate species, including giant protozoans
(xenophyophores), vase-shaped white sponges, actiniarians, antipatharian corals, hydroids, bryozoans, asteroids,
ophiuroids, echinoids, holothurians, and crustaceans.
The distribution of cold-water coral has been severely reduced in the area over the last 30 years.
The deep-water sharks C. coelolepis and C. squamosus are also listed in the OSPAR list. Both occur in the area, but
there is no information to indicate that this area is important for either species in the sense of having a significant
proportion of the population or higher density than other areas of similar depth in the region.
Both Zino’s petrel (endangered) and Fea’s petrel (near threatened) are listed on the IUCN Red List. A further five
species of seabirds listed in Annex I of the European Union Bird’s Directive are found within the area. However,
tracking for the two petrel species (data in Figure 2 of the proposal; OSPAR/NEAFC/CBD, 2011) appears to show that
the area is of relatively low importance (5 to 10% of tracked birds) during a very short period (one month).
Knowledge of cetaceans in the area is poor, but the critically endangered northern right whale (Eubalaena glacialis)
has been observed in this area. However, this single observation is insufficient to demonstrate importance for this
species.
Areas that contain a relatively high proportion of
Vulnerability,
X
sensitive habitats, biotopes, or species that are
fragility,
sensitivity, or functionally fragile (highly susceptible to
degradation or depletion by human activity or by
slow recovery
natural events) or with slow recovery.
Explanation for ranking
It is uncertain how “a relatively high proportion” is defined in this context, but there is good evidence for vulnerable
habitats and benthic species in the area (records of cold-water coral reefs and carbonate mounds, and indicator species
for coral gardens, deep-water sponge aggregations). Distribution is not uniform across the area and many of the areas
where they occur are now protected as VMEs.
There is a high diversity of corals, including bamboo coral (Isididae), black coral (Antipatharia), as well as the reefforming stony corals (Scleractinia), though some of these may now be reduced in distribution and occurring in patches.
Cold-water coral habitats are easily impacted and recover very slowly. Some species of cold-water corals can live for
more than 4000 years.
Many of the demersal fish have life histories of deep-water fish fauna with very slow recovery times as a result of their
slow reproductive rate compared to pelagic fish. These fish may be more exposed to fishing pressure because trawlable
habitat is more common in this area than is typical at these depths. Stocks have already been diminished in some areas.
There is good support for qualification under this criterion from the occurrence of vulnerable marine ecosystems,
including stony corals, carbonate mounds, possible coral gardens and deep-sea sponge aggregations, and an active cold
seep. Although comparative studies have not been done, it is probable that occurrence of corals in the Rockall–Hatton
area is higher than in other areas of comparable depth and latitude. This would therefore constitute a “relatively high
proportion”.
The species or habitats discussed in this rationale are generally found in depths above 1500 m and thus this proposed
EBSA should be limited to this depth contour.
Areas containing species, populations, or
Biological
X
communities with comparatively higher natural
productivity
biological productivity.
Explanation for ranking
It is likely that pelagic production may be enhanced relative to surrounding areas due to upwelling, but benthic
secondary production in deep-water environments is generally considered to be low compared to other environments.
Areas containing a comparatively higher diversity
Biological
X
of ecosystems, habitats, communities, or species,
diversity
or with higher genetic diversity.
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111
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Know
Low
Some
High
Explanation for ranking
The area comprises a patchwork of habitats with species changing consistently with both habitat type and increasing
depth. Some habitats are threatened by direct impacts (e.g. bottom fishing), others may suffer indirectly (e.g. through
the creation of sediment plumes by impacts of fishing gear in sensitive areas). Seabed communities include cold-water
corals, rocky reefs, carbonate mounds, polygonal fault systems, sponge aggregations, and steep and gentle sedimented
slopes. Cold-water corals provide diverse habitats for other invertebrates and fish.
This area spans more than one biogeography province; consequently, overall diversity is likely to be higher than in
other areas with comparable depth and habitat range. Rare habitats such as cold seeps and highly diverse habitats such
as cold-water coral reef and rubble further contribute to the overall diversity.
Proposal for a different configuration of EBSAs than those presented in the OSPAR/NEAFC/CBD Workshop
report
Proposed EBSAs 1, 2, and 3 (Reykjanes Ridge south of Iceland EEZ, Charlie-Gibbs Fracture Zone and Subpolar Frontal
Zone of the Mid-Atlantic Ridge, and Mid-Atlantic Ridge north of the Azores) all encompass the hard substrates running
roughly north–south in the higher elevations of the Mid-Atlantic Ridge, and for proposed EBSAs 1 to 3 the southern
boundary of each aligns with the northern boundary of the next. The boundaries between them were defined primarily by
the extreme limits of the position of the east–west-oriented Subpolar Front, a major pelagic oceanographic feature in
proposed EBSA 2 that moves seasonally northward spring and summer) and southward (autumn and winter).
The Subpolar Front has affinities with the Charlie-Gibbs Fracture Zone, but not with the Mid-Atlantic Ridge. If the
Charlie-Gibbs Fracture Zone, running roughly east to west, and associated Subpolar Frontal Zone were treated separately
from the Mid-Atlantic Ridge, then all the areas delineated by the features of the Mid-Atlantic Ridge specified for the
proposed EBSAs 1, 2, and 3 would share a consistent geomorphological feature (the emergent hard substrates primarily
of volcanic origin) with associated benthic fauna present from the northern boundary of proposed EBSA 1 to the southern
boundary of proposed EBSA 3, with the Charlie-Gibbs Fracture Zone itself simply serving as an interruption in this
feature.
The entire Mid-Atlantic Ridge feature would score “Some” or “High” on several criteria, and for generally the same
biological rationales for the entire ridge. The species composition of the benthic biota does change from north to south,
but aside from the structural interruption caused by the transverse fractures, there is no strong evidence that discontinuities
in benthic community composition exist along the ridge. Thus, an alternative area to proposed EBSAs 1, 2, and 3 can be
justified along the entire Mid-Atlantic Ridge in the OSPAR/NEAFC area, defined by the features specified in the
description of proposed EBSA 1, and ranked as “Some” or “High” on several EBSA criteria with a common justification
for that entire area.
A second alternative EBSA could then be proposed, consisting of the Charlie-Gibbs Fracture Zone and Subpolar Frontal
Zone, taken together. This area would have its own set of ecological properties and associated rankings on the EBSA
criteria. It would be ranked “Some” or “High” on several criteria for justifications specific to the Fracture Zone and
Subpolar Front, but in several cases for justifications very different from that of the Mid-Atlantic Ridge.
These two potential proposed EBSAs would replace proposed EBSAs 1, 2, and 3 from the OSPAR/NEAFC/CBD
Workshop report. It would also require a separate consideration of seabird foraging in the southern third of the area,
jointly with the additional analyses already recommended for the OSPAR/NEAFC/CBD Workshop proposed EBSAs 5–
8.
Alternative proposed EBSA for the Mid-Atlantic Ridge
The Mid-Atlantic Ridge runs from the southern boundary of the Icelandic EEZ to the northern boundary of the Portuguese
EEZ in the Azores and includes all area above a depth contour that runs in the deeper of two properties:
1.
2.
112
Including a large portion (arbitrarily, perhaps 90%) of all hard volcanic substrates; habitats are reported to host
the larger known coral deposits and their associated communities.
Included a large portion (arbitrarily, 90%) of the records of large sponge communities in the overall Mid-Atlantic
Ridge.
ICES Advice 2013, Book 1
In addition the proposed area should include all known hydrothermal vents along the ridge, if any of these are deeper than
the contours meeting the properties above.
Evaluation of the proposed area against the EBSA criteria
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
High
Know
The area contains either (i) unique (“the only one of
X
(X)
its kind”), rare (occurs only in few locations), or
endemic species, populations, or communities,
and/or (ii) unique, rare, or distinct habitats or
ecosystems, and/or (iii) unique or unusual
geomorphological or oceanographic features.
Explanation for ranking
The qualified “High” ranking is for restricted areas of the few known hydrothermal vents along the ridge. These are
globally rare features; only a small part of the area proposed here meets this EBSA criterion.
Uniqueness
rarity
or
The MarEco sampling of corals and sponges reported several species new to science as it sampled the Mid-Atlantic
Ridge. However, it is not possible to draw a firm conclusion on the presence of unique species along the ridge until
more extensive sampling is undertaken.
Areas that are required for a population to survive
Special
X
importance for and thrive.
life-history
stages of species
Explanation for ranking
Although many populations undoubtedly complete their life cycles within the harder-substrate areas of the MidAtlantic Ridge, this would be true of any marine area of comparable size. There is no evidence that the life history of
any species is strongly dependent on any specific features of the area proposed as an alternative EBSA.
There is evidence from other areas of the Northeast Atlantic that areas of high coral density may be important as eggcase and nursery areas of deep-water sharks and rays. The area proposed here is targeted on the depths and substrates
associated with higher coral and sponge densities, and if sharks and rays also concentrate spawning and early
development in these habitats, then the score would be “Some” or “High” on this criterion as well. However, it has not
yet been documented that skates and rays do preferentially use the coral and sponge formations for these life history
functions in the Mid-Atlantic Ridge.
For the more southern portions of the Mid-Atlantic Ridge in particular, there are reports of areas being important for
foraging by seabirds, including Cory’s shearwater. The evidence available is not considered strong, however, and this
aspect of the ecological functionality of the central ridge area should be considered as part of the reanalysis of EBSAs
5–8 proposed in the OSPAR/NEAFC/CBD Workshop report.
Importance for Areas containing habitats for the survival and
X
recovery of endangered, threatened, or declining
threatened,
endangered, or species, or areas with significant assemblages of
such species.
declining
species and/or
habitats
Explanation for ranking
There are large deposits of corals and sponges found in the alternative area proposed by ICES as meeting this criterion.
Habitats containing these species are listed by OSPAR and are also VME indicator species, and the majority of these
would be included in the alternative proposed EBSA. Additional explanation regarding corals and sponges is included
in the rationale for the criterion on Vulnerability.
The possible role of the alternative proposed Mid-Atlantic Ridge area in the life histories of sharks and rays is discussed
in the criterion on Vulnerability and Sensitivity. If a dependency between the breeding or early life history of threatened
or endangered skates or rays were documented, there would be additional justification for a “High” ranking of this
criterion.
ICES Advice 2013, Book 1
113
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
High
Know
Areas that contain a relatively high proportion of
sensitive habitats, biotopes, or species that are
functionally fragile (highly susceptible to
degradation or depletion by human activity or by
natural events) or with slow recovery.
Explanation for ranking
Vulnerability,
fragility,
sensitivity, or
slow recovery
X
With regard to corals and sponges, Mortensen et al. (2008) found cold-water corals “at every sample station …
observed at depths between 800 and 2400 m, however were commonly found shallower than 1400 m …, with species
richness being very high. … no major reef structures were recorded, with the maximum colony size approximately 0.5
m in diameter. The number of coral taxa was strongly correlated with the percentage cover of hard bottom substrate
….” The area proposed here is targeted at the seamount peaks and slopes where hard substrates dominate. For sponges,
no actual large expanses of sponge reef were reported in the OSPAR/NEAFC/CBD Workshop report. However, the
pro forma in that report notes that overall sampling of the area is patchy and cites three studies that found local patches
with high densities of sponges, although in no cases were the sizes of the patches documented.
If research finds that deep-sea sharks and rays use the denser coral deposits as important spawning and nursery grounds,
as has been reported in the Hatton–Rockall Bank area proposed by ICES, then there would be additional justification
for a score of “Some” on this criterion.
Areas containing species, populations, or
Biological
X
communities with comparatively higher natural
productivity
biological productivity.
Explanation for ranking
Although benthic productivity of the alternative proposed Mid-Atlantic Ridge EBSA may be higher than benthic
productivity on the abyssal plain, productivity integrated over the entire water column and seafloor seems typical of
systems of comparable depth and latitude globally.
Areas containing comparatively higher diversity of
Biological
X
ecosystems, habitats, communities, or species, or
diversity
with higher genetic diversity.
Explanation for ranking
The presence of comparatively large coral and sponge formations, and the documented high diversity of benthic and
associated fish when corals or sponges are present in moderate or high density imply that some areas along the ridge
may have high diversity. From north to south there is a mingling of benthic and demersal fish faunas characteristic of
both cooler northern and warmer southern ocean environments, giving the area as a whole a somewhat higher net
biological diversity, even if the diversity in any individual site is not markedly enhanced. Aside from the benthic
communities of somewhat restricted distribution associated with the biogenic habitats, the biodiversity otherwise
appears typical of biotic communities at similar depths and latitude.
Alternative proposed EBSA – The Charlie-Gibbs Fracture Zone and Subpolar Frontal Zone
The area would include:
i.
ii.
Subpolar Frontal Zone (coinciding with the Charlie-Gibbs Fracture Zone): The northern and southern
boundaries for this feature should be set according to the known northernmost and southernmost locations of the
frontal system (at approximately 53°N and 48°N). The eastern and western boundaries for this feature should be
set according to the eastern and westernmost extension of the Charlie-Gibbs Fracture Zone (at approximately
27°W and 42°W).
Charlie-Gibbs Fracture Zone: The eastern and western boundaries for this feature should be set according to the
east–west extension of the Fracture Zone (at approximately 27°W and 42°W). The northern and southern seabed
boundaries for this feature should be set with a view to encompass the characteristic topography and substrates
of the Fracture Zone.
Any area of the seafloor and associated benthos that lies below the pelagic feature i) (the total area occupied by the
Subpolar Front during its annual movement) but does not meet feature ii) is not included in the area proposed as meeting
EBSA criteria. Only those parts of the water column where the Subpolar Front is prominent at some time during the year
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ICES Advice 2013, Book 1
are proposed as meeting one or more of the EBSA criteria. Moreover, in the entire pelagic area described by i), at any
given time only that part of the total area where the Subpolar Front is located would be expected to meet some of the
criteria. Although maps will show that the full pelagic area is proposed as part of this complex EBSA, any conservation
measures for ecological properties of the water column would need to take into account the position of the Subpolar Front
to be fully effective.
Evaluation of the proposed area against the EBSA criteria
CBD
EBSA
Criterion
Description
The area contains either (i) unique (“the only one of
its kind”), rare (occurs only in few locations), or
endemic species, populations, or communities,
and/or (ii) unique, rare, or distinct habitats or
ecosystems, and/or (iii) unique or unusual
geomorphological or oceanographic features.
Explanation for ranking
Uniqueness
rarity
or
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
High
Know
X
The Charlie-Gibbs Fracture Zone is a set of geomorphological features unique to the entire North Atlantic, and the
Subpolar Front is an oceanographic feature also unique to the Northeast Atlantic. Together these features justify a
“High” score for this criterion.
Areas that are required for a population to survive
Special
X
importance for and thrive.
life-history
stages of species
Explanation for ranking
No evidence is available suggesting a significant importance of the area for life-history stages of widespread species
in comparison with other marine areas of similar size and depth range. It is possible that there are species with special
affinities for the unique geophysical features of the deep faults, but clear documentation of species with such affinities
was not found in the references provided by the OSPAR/NEAFC/CBD Workshop report, and was not otherwise known
to ICES.
Importance for Areas containing habitats for the survival and
X
recovery of endangered, threatened, or declining
threatened,
endangered or species, or areas with significant assemblages of
such species.
declining
species and/or
habitats
Explanation for ranking
There is good evidence that the area contains a significant assemblage of species and habitats that are assessed to be
threatened, endangered, or declining, including leafscale gulper shark (Centrophorus squamosus), gulper shark
(Centrophorus granulosus), Portuguese dogfish (Centroscymnus coelepis), Sei whale (Balaenoptera borealis), sperm
whale (Physeter macrocephalus), leatherback turtle (Dermochelys coriacea), as well as cold-water coral reefs and
deep-sea sponge aggregations. Depending on the species, the special features of the Fracture Zone and the Subpolar
Front are inferred to provide important biological functions to the species which aggregate along each one.
Areas that contain a relatively high proportion of
Vulnerability,
X
sensitive habitats, biotopes, or species that are
fragility,
sensitivity, or functionally fragile (highly susceptible to
degradation or depletion by human activity or by
slow recovery
natural events) or with slow recovery.
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115
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
High
Know
Explanation for ranking
The Charlie-Gibbs Fracture Zone geophysical structure provides habitats for a number of sensitive/vulnerable species
and communities both on soft and hard substrate and in the associated water column. In particular biogenic habitats
such as those formed by cold-water corals and sponges are considered vulnerable, are often fragile, and slow (if at all)
to recover from damage. Some fish species associated with the Fracture Zone and the Subpolar Front also show slow
growth, late maturity, irregular reproduction, and long generation time, as well as community characteristics of high
diversity at low biomass. However, the documentation that the species with vulnerable life histories are especially
closely affiliated with the Fracture Zone and frontal habitats is weak, and it is clear that these vulnerable species and
biogenic habitats are not consistently present throughout the entire Fracture Zone and Subpolar Front.
Areas containing species, populations, or
Biological
X
(X)
communities with comparatively higher natural
productivity
biological productivity.
Explanation for ranking
There is good evidence that, because of the Subpolar Front, the pelagic area where the front is located at any particular
time is characterized by an elevated abundance and diversity of many taxa, including an elevated standing stock of
phytoplankton. This justifies a ranking of “High” for the pelagic area around the Subpolar Front, as it moves seasonally.
However, there is no evidence of relatively elevated productivity in the benthic communities of the Fracture Zone.
Areas containing a comparatively higher diversity of
Biological
X
ecosystems, habitats, communities, or species, or
diversity
with higher genetic diversity.
Explanation for ranking
The area of the Fracture Zone is characterized by a very high structural complexity, offering a diverse range of habitats.
The area of the Subpolar Front is a feature where species are documented to assemble seasonally. Consequently, both
features characterizing this area contribute to a relatively higher diversity of ecosystems, habitats, communities, and
species in comparison to other areas of the Northeast Atlantic.
Proposed EBSAs for which there is insufficient scientific justification
For five of the ten areas proposed as meeting one or more EBSA criteria in the OSPAR/NEAFC/CBD Workshop report,
ICES concluded that there is insufficient scientific justification at this time to propose their delineated area, or any subset
of it, as meeting EBSA criteria. In all cases ICES recommends that additional information needs to be collated and
analysed, and a new evaluation be conducted when those results are available. ICES provides reasoning for its advice and
recommendations for further work in each of these areas below.
Area 5. Around the Pedro Nunes and Hugo de Lacerda seamounts and
Area 6. Northeast Azores–Biscay Rise
The OSPAR/NEAFC/CBD Workshop concluded that both areas ranked as “High” on criterion Special Importance to Life
History of Species, and “Some” on criteria Uniqueness and Rarity; Importance to Threatened, Endangered, or Declining
Species; and Vulnerability, Sensitivity, etc., the latter primarily for seabirds. ICES questions the basis for these
conclusions, noting that the data used to assess all the criteria specified were incomplete and often incorrectly interpreted,
with the proposed boundaries not matching the information in the cited sources.
ICES recommends that all available data on foraging activity of the Zino’s petrel, Cory’s shearwater, and other relevant
species be examined. This should include published and any other available data. Occurrence data may be used as well,
provided the rationale details how occurrence and foraging data are used to derive EBSA boundaries.
Area 7. Evlanov Seamount region
The OSPAR/NEAFC/CBD Workshop concluded that the area they delineated ranked as “High” on criterion Importance
to Threatened, Endangered, or Declining Species, and “Some” on criteria Uniqueness and Rarity; Special Importance to
Life History of Species; and Vulnerability, Sensitivity, etc., the latter primarily for seabirds. ICES questions the basis for
these conclusions, noting that the data used to assess all the criteria specified were incomplete and often incorrectly
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ICES Advice 2013, Book 1
interpreted, with the proposed boundaries not matching the information in the cited sources. In particular the sample sizes
for Fea’s petrel were very small, and the information for sooty shearwater did not seem to differentiate the proposed
EBSA area from most of surrounding area.
ICES advises not to proceed with proposing any portion of this area as an EBSA at this time, but rather undertake further
collation and analysis of information and reconsider when the additional work is completed.
Area 8. Northwest of Azores EEZ
The OSPAR/NEAFC/CBD Workshop concluded that the area they delineated ranked as “High” on criteria Special
Importance for Life History of Stages of Species and Importance for Threatened, Endangered or Declining Species, and
“Some” on criteria Uniqueness and Rarity; Vulnerability, Sensitivity, etc.; and Biological Diversity, the latter primarily
for seabirds. ICES questions the basis for these conclusions, noting that the data used to assess all the criteria specified
were incomplete and often incorrectly interpreted, with very small sample sizes for some of the species’ (e.g. Zino’s
petrel) foraging areas, and questionable interpretation of the foraging areas of Cory’s shearwater.
ICES does not support this area going forward as presented in the OSPAR/NEAFC/CBD EBSA Workshop report. ICES
advises that improvements are needed to the supporting evidence in the narrative for criteria related to Special Importance
for Life History Stages of Species and Importance for Threatened, Endangered or Declining Species and/or Habitats. It
is necessary to augment information on how the area is being used (feeding, conditioning, migration) for the survival and
recovery of the species and to put some scale on its importance to the species (some of which have very restricted breeding
sites in the larger area). It is also necessary to document the proportion of species that are highly susceptible to degradation
or depletion by human activity, in this case bycatch in longline fisheries.
Area 9. The Arctic Front – Greenland/Norwegian seas
The OSPAR/NEAFC/CBD Workshop concluded that the area they delineated ranked as “High” on criteria Special
Importance to Life History of Species; Importance to Threatened, Endangered, or Declining Species; Biological
Productivity; and Biological Diversity. ICES questions the basis for these conclusions, noting that (1) for several features
the area proposed as meeting criteria were not noticeably different from the surrounding areas; (2) some of the rankings
regarding importance appeared to be inferred from a belief that the area is high in productivity, but the rankings were not
demonstrated otherwise; and (3) publications with contrasting conclusions were found for some of the key references
cited in the OSPAR/NEAFC/CBD Workshop report.
ICES recommends not to proceed with the proposed Arctic Front EBSA. There is no evidence of enhanced productivity
at the Arctic Front which is the main rationale used to justify the proposed EBSA. However, there seems to be
circumstantial evidence for an enhanced production that may attract feeding animals in the areas around and south of Jan
Mayen, including the Jan Mayen Front. If parts of this area are located in the high seas, further analyses should be
undertaken to determine if this area meets the EBSA criteria.
Sources
CBD. 2007. Expert Workshop on Ecological Criteria and Biogeographic Classification Systems for Marine Areas in Need
of Protection. 2–4 October 2007, Azores, Portugal. (http://www.cbd.int/doc/meetings/mar/ewsebm01/official/ewsebm-01-02-en.pdf).
CBD. 2008. CBD Decision IX/20 on Marine and Coastal Biodiversity. (http://www.cbd.int/doc/decisions/cop-09/cop-09dec-20-en.pdf).
CBD. 2009. Expert Workshop on Scientific and Technical Guidance on the Use of Biogeographic Classification Systems
and Identification of Marine Areas beyond National Jurisdiction in Need of Protection. 29 September–2 October
2009, Ottawa, Canada. (https://www.cbd.int/doc/meetings/sbstta/sbstta-14/information/sbstta-14-inf-04-en.pdf).
CBD.
2010.
CBD
Decision
X/29
on
Marine
and
Coastal
Biodiversity.
(https://www.cbd.int/decision/cop/default.shtml?id=12295).
German, C. R., and Parsons, L. M. 1998. Distributions of hydrothermal activity along the Mid-Atlantic Ridge: interplay
of magmatic and tectonic controls. Earth and Planetary Science Letters, 160: 327–341.
German, C. R., Briem, J., Chin, C., Danielsen, M., Holland, S., James, R., Jónsdottir, A., Ludford, E., Moser, C., Ólafsson,
J., Palmer, M. R., and Rudnicki, M. D. 1994. Hydrothermal activity on the Reykjanes Ridge: the Steinahóll ventfield at 63°06’N. Earth and Planetary Science Letters, 121: 647–654.
ICES. 2013a. Vulnerable deep-water habitats in the NEAFC Regulatory Area. In Report of ICES Advisory Committee,
2013, Section 1.5.5.1. ICES Advice, 2013, Book 1.
ICES. 2013b. Report of the Workshop to Review and Advise on EBSA Proposed Areas (WKEBSA), 27–31 May 2013,
Copenhagen, Denmark. In draft.
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Mironov, A., and Gebruk, A. 2007. Deep-sea benthos of the Reykjanes Ridge: biogeographic analysis of the fauna living
below 1000 m. Report on preliminary phase of the project patterns and processes of the ecosystems of the northern
Mid-Atlantic (Mar-Eco).
(http://www.mareco.no/sci/component_projects/epibenthos/deep-sea_benthos_of_the_reykjanes_ridge).
Mortensen, P. B., Buhl-Mortensen, L., Gebruk, A. V., and Krylova, E. M. 2008. Occurrence of deep-water corals on the
Mid-Atlantic Ridge based on Mar-Eco data. Deep-Sea Research, 55: 142–152.
Olafsson, J., et al. 1991. A sudden cruise off Iceland. RIDGE Events Newsletter, 2(2): 35–38.
OSPAR/NEAFC/CBD. 2011. Report of the Joint OSPAR/NEAFC/CBD Scientific Workshop on the Identification of
Ecologically or Biologically Significant Marine Areas (EBSAs) in the North-East Atlantic. 8–9 September 2011,
Hyères, France. Annex 11.
Søiland, H., Budgell, W. P., and Knutsen, Ø. 2008. The physical oceanographic conditions long the Mid-Atlantic Ridge
north of the Azores in June–July 2004. Deep-Sea Research II, 55: 29–44.
United Nations. 2004. UNGA Resolution 58/240.
(http://daccess-dds-ny.un.org/doc/UNDOC/GEN/N03/508/92/PDF/N0350892.pdf?OpenElement).
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Annex 1.5.6.5.1
Revised pro forma for the Arctic Ice habitat
Annex 1
Joint OSPAR/NEAFC/CBD Scientific Workshop on the Identification of Ecologically or Biologically
Significant Marine Areas (EBSAs) in the North-East Atlantic
Hyères (Port Cros), France: 8 – 9 September 2011
________________________________________
EBSA identification proforma for the North-East
Atlantic - 10
Title/Name of the area - The Arctic Ice habitat - multiyear ice, seasonal ice and marginal ice zone
Presented by WWF and reviewed by Participants at the Joint OSPAR/NEAFC/CBD Scientific Workshop on
the Identification of Ecologically or Biologically Significant Marine Areas in the North-East Atlantic
Contact: Sabine Christiansen [email protected]
Abstract
The permanently ice covered waters of the high Arctic provide a range of globally unique habitats associated
with the variety of ice conditions. Multi-year sea ice only exists in the Arctic and although the projections of
changing ice conditions due to climate change project a considerable loss of sea ice, in particular multiyear
ice, the Eurasian Central Arctic high seas are likely to at least keep the ice longer than many other regions in
the Arctic basin. Ice is a crucial habitat and source of particular foodweb dynamics, the loss of which will affect
also a number of mammalian and avian predatory species. The particularly pronounced physical changes of
Arctic ice conditions as already observed and expected for the coming decades, will require careful ecological
monitoring and eventually measures to maintain or restore the resilience of the Arctic populations to quickly
changing environmental conditions.
Introduction
Up until today most of the Eurasian part of the Arctic Basin, and in particular the high seas area in the Arctic
Ocean (the waters beyond the 200 nm zones of coastal states, i.e. Norway, Russia, USA, Canada and
Greenland/Denmark) is permanently ice covered. However, in recent years, much of the original multiyear
pack ice has been replaced by seasonal (1 year) ice which made it possible for research and other vessels to
reach the pole. In addition, the former fast pack-ice is now increasingly broken up by leads. This structural
change in the Arctic ice quality will result in a substantial increase in light penetrating the thin ice and water
column, in conjunction with the overall warming of surface waters and increased temperature and salinity
stratification due to the melting of ice.
In the near future, up to the end of the century, the permanent ice cover is expected to disappear completely
in some models (Anisimov et al., 2007). This will result in significant changes in the structure and dynamics of
the high Arctic ecosystems (CAFF, 2010; Gradinger, 1995; Piepenburg, 2005; Renaud et al., 2008;
Wassmann, 2008, 2011) which should be closely monitored (Bluhm et al., 2011) as already envisaged by the
Arctic Council (Gill et al., 2011; Mauritzen et al., 2011).
Therefore, the area proposed here as EBSA is of particular scientific interest and may in the longterm, become
relevant for the commercial exploitation of resources.
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Location
The Ecologically or Biologically Significant Marine Area (EBSA) proposed focusses on the presently
permanently ice-covered waters in the OSPAR/NEAFC maritime areas, including the high seas section in the
Central Arctic Basin north of the 200 nm zones of coastal states (see Fig. 1 attached). Therefore, the
boundaries proposed extend from the North Pole (northernmost point of OSPAR/NEAFC maritime areas) to
the southern limit of the summer sea ice extent and marginal ice zone, including on the shelf of East Greenland.
The proposal currently only relates to features of the water column. Two legal states have to be distinguished:
the Central Arctic high seas waters north of the 200 nm zones of adjacent coastal states, generally north of
84° N, and the waters within the Exclusive Economic Zones of Greenland, Russia and the fisheries protection
zone of Norway around Svalbard. Figure 1 distinguishes between the high seas beyond national jurisdiction
for which the „Joint OSPAR/NEAFC/CBD Scientific Workshop on the Identification of Ecologically or
Biologically Significant Marine Areas (EBSAs) in the North-East Atlantic“ has a mandate8, and
national/nationally administered waters within the 200 nm zone, within which the OSPAR Contracting Parties
have the responsiblity to report candidate EBSAs to the Convention on Biodiversity EBSA repository (OSPAR
Commission, 2011).
The seafloor of the respective region will likely fall on the extended continental shelves of several coastal
states. It belongs to the „Arctic Basin“ region of (Gill et al., 2011).
The coordinates of the overall area, as well as the high seas section are provided in Annex 1 (in decimals,
shape files provided):
c.f. Figure 1: Location of the Arctic Ice „Ecologically or Biologically Significant Area“ (EBSA) proposed by WWF
in September 2011. The position of the Arctic and polar fronts was redrawn after (Rey, 2004, Fig. 5.7).
Feature description
The Ecologically or Biologically Significant Marine Area (EBSA) proposed focusses on the presently
permanently ice-covered waters in the OSPAR/NEAFC maritime areas, including the high seas section in the
Central Arctic Basin north of the 200 nm zones of coastal states, and the marginal ice zone (where the ice
breaks up, also called seasonal ice zone) along its southern margins (see Fig. 1 attached). Due to the inflow
of Atlantic water along the shelf of Svalbard, and the concurrent outflow of polar water and ice on the Greenland
side of Fram Strait, the southern limit of the summer sea ice extent is much further south in the western
compared to the eastern Framstrait, and in former times extended all along the Greenland coast.
The high seas section of the OSPAR maritime area in the Central Arctic ocean is generally north of 84° N and
is until today fully ice-covered also in summer, although the quantity of multiyear ice has already substantially
decreased and the 1-year ice leaves increasingly large leads and open water spaces. The ice overlays a very
deep water body of up to 5000 m depth far away from the surrounding continental shelves and slopes of
Greenland and the Svalbard archipelago. The Nansen-Gakkel Ridge, a prolongation of the Mid-Atlantic Ridge
north of the Fram Strait is structuring the deep Arctic basin in this section, separating the Central Nansen Basin
to the south from the Amundsen Basin to the north. Abundant hydrothermal vent sites have been discovered
on this ridge at about 85° 38 N (Edmonds et al., 2003).
North of Spitsbergen, the Atlantic water of the West Spitsbergen Current enters the Arctic basin as a surface
current. At around 83° N, a deep-reaching frontal zone separates the incoming Atlantic and shelf waters from
those of the Central Nansen Basin (Anderson et al., 1989), as reflected in ice properties, nutrient
concentrations, zooplankton communities, and benthic assemblages (Hirche and Mumm, 1992, and literature
quoted). This water subsequently submerges under the less dense (less salinity, lower temperature) polar
water and circulates, in opposite direction to the surface waters and ice, counterclockwise along the continental
rises until turning south along the Lomonossov Ridge and through Fram Strait as East Greenland Current
south to Danmark Strait (Aagaard, 1989; Aagaard et al., 1985). Connecting the more fertile shelves with the
8 Participant Briefing for a Joint OSPAR/NEAFC/CBD Scientific Workshop on the Identification of Ecologically or
Biologically Significant Marine Areas (EBSAs) in the North-East Atlantic. Invitation Annex 2, 2011
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deep central basin, these modified Atlantic waters supply the waters north of the Nansen-Gakkel Ridge, in the
Amundsen basin, with advected organic material and nutrients which supplement the autochtonous production
(Mumm et al., 1998). Due to the import of organic biomass from the Greenland Sea and the Arctic continental
shelves, part of which may not be kept in the food web due to the polar conditions, the Arctic Ocean may also
represent an enormous carbon sink (Hirche and Mumm, 1992).
In the Fram Strait, the region between Svalbard to the east and Greenland to the west, the East Greenland
Current is the main outflow of polar water and ice from the Arctic Basin (Maykut, 1985) (Aagaard and
Coachman, 1968). The polar front (0° C isotherm and 34.5 isohaline at 50 m depth) extends approximately
along the continental shelf of Greenland, separating the polar surface water from the Arctic (Intermediate)
water and the marginal ice zone to the east (e.g. Aagaard and Coachman, 1968; Paquette et al., 1985). The
ice cover is densest in polar water, its extent to the east depends on the wind conditions (compare also Angelen
et al., 2011; Wadhams, 1981).
The seasonal latitudinal progression of increasing and diminishing light levels, respectively, is the determining
factor for the timing of the phytoplankton-related pelagic production. Therefore, the springbloom and ice break
up progress from south to north in spring, reaching the Arctic area by about June/July. Because the currents
in Fram Strait move in opposite direction, the polar East Greenland Current to the south, and the Atlantic West
Spitsbergen Current to the north, there is a delay of about a month between biological spring and summer
between the polar and the Atlantic side (Hirche et al., 1991). Therefore sea ice and the effect of melting ice
are important determinants of the ecosystem processes all along the East Greenland polar front from the
Greenland Sea through Fram Strait to the Arctic Basin (Legendre et al., 1992; Wassmann, 2011).
Ice situation
The Arctic Ocean develops towards a one-year instead of a multi-year sea-ice system with consequences for
the entire ecosystem, including ecosystem shifts, biodiversity loss, for water mass modifications and for its role
in the global overturning circulation. At its maximum, sea-ice covers 4.47 million km² in the Arctic Basin (Gill et
al., 2011): According to data from ice satellite observations in 1973-76 (NASA, 1987, in (Gill et al., 2011)),
permanent ice occupied 70-80% of the Arctic Basin area, and the interannual variability of this area did not
exceed 2%. Seasonal ice occupied 6-17% (before the melting period of the mid-1970s). Only in the first decade
of the 21st century, the permanent-ice area decreased to 6% in February 2008, concurrent with a rapid
increase in seasonal- ice. Whereas multiyear ice used to cover 50-60% of the Arctic, it covered less than 30%
in 2008, after a minimum of 10% in 2007. The average age of the remaining multiyear ice is also decreasing
from over 20 % being at least six years in the mid- to late 1980s, to just 6% of ice six years old or older in 2008.
c.f. Figure 2: Modelled ice age distribution in 1985-2000 (left) compared to February 2008 (right) (CAFF,
2010).
This trend is likely to amplify in the coming years, as the net ocean-atmosphere heat output due to the current
anomalously low sea ice coverage has approximately trippled compared to previous years, suggesting that
the present sea ice losses have already initiated a positive feedback loop with increasing surface air
temperatures in the Arctic (Kurtz et al., 2011).
About 10% of the sea ice in the Arctic basin is exported each year through Fram Strait into the Greenland Sea
(Maykut, 1985) which is therefore major sink for Arctic sea ice (Kwok, 2009). From 2001 to 2005, the summer
ice cover was so low on the East Greenland shelf, that it was more of a marginal ice zone (Smith Jr and Barber,
2007), however the subsequent record lows in overall Arctic ice cover brought about an increase in ice cover
off Greenland, which minimised the extent of the North East Water Polynia on the East Greenland shelf9, a
previously seasonally ice-free stretch of water (Wadhams, 1981).
Ice related biota
9
http://www.issibern.ch/teams/Polynya/
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Allover the Arctic, an inventory of ice-associated biota presently counts over 1000 protists, and more than 50
metazoan species (Bluhm et al., 2011). The regionally very variable ice fauna (depends i.e. on ice age,
thickness, origin) consists of sympagic biota living within the caverns and brine channels of the ice, and
associated pelagic fauna. The most abundant and diverse sympagic groups of the ice mesofauna in the Arctic
seas are amphipods and copepods. Polar cod (Boreogadus saida) and partly Arctic cod (Arctogadus glacialis)
are dependent on the sympagic macro- and mesofauna for food, themselves being important food sources for
Arctic seals (such as ringed seal Phoca hispida) and birds, for example black guillemots Cephus grylle
(Bradstreet and Cross, 1982; Gradinger and Bluhm, 2004 and literature reviewed; Horner et al., 1992; Süfke
et al., 1998).
The higher the light level in the ice, the higher is the biomass of benthic algae as well as meiofauna and
microorganisms within the ice (Gradinger et al., 1991). Decreasing snow cover induces a feedback loop with
enhanced algal biomass increasing the heat absorption of the ice which leads to changes in the ice structure,
and ultimately the release of algae from the bottom layer (Apollonio, 1961 in Gradinger et al., 1991). Because
of the distance to land and shelves, and the thickness and internal structure of the multiyear pack ice over
deeper water, this type of ice has a fauna of its own (Carey, 1985; Gradinger et al., 1991). Arctic multiyear ice
floes can have very high algal biomasses in the brine channels and in the bottom centimeters which serves as
food for a variety of proto- and metazoans, usually smaller than 1 mm, over deep water (Gradinger et al.,
1999). In the central Arctic, ice algal productivity can contribute up to 50 % of the total primary productivity,
with lower contributions in the sea ice covered margins (Bluhm et al., 2011).
In the boundary layer between ice floes and the water column, another specific community exists which forms
the link between the ice based primary production and the pelagic fauna (Gradinger, 1995): large visible bands
of diatoms hang down from the ice, exploited by amphipods such as Gammarus wilkitzki, and occacionally by
water column copepods such as Calanus glacialis, which are important prey of for example polar cod
Boreogadus saida. The caverns, wedges and irregularities of the ice provide important shelter from predators
for larger ice associated species and provide an essential habitat for these species (Gradinger and Bluhm,
2004).
During melt, the entire sympagic ice biota are released into the water column where they may initiate the spring
algal plankton bloom (Smith and Sakshaug, 1990) or they may sink to the sea floor and serve as an episodic
and first food pulse for benthic organisms before pelagic production begins (Arndt and Pavlova, 2005). In
particular the shallow shelves and the shelf slope benthos has been shown to profit of this biomass input,
reflected in very rich benthic communities (Klitgaard and Tendal, 2004; Piepenburg, 2005).
The role of the polar front and marginal ice zone for the production system
Primary production in the Arctic Ocean is primarily determined by light availability, which is a function of ice
thickness, ice cover, snow cover, light attenuation), the abundance of both ice algae and phytoplankton,
nutrient availability and surface water stratification. Generally, the spring bloom occurs later further north and
in regions with a thick ice and snow cover. The current production period in the Arctic Ocean may extend to
120 days per year, with a total annual primary production in the central Arctic Ocean of probably up to 10 g C
m-2 (Wheeler et al., 1996).
Ice algae start primary production already at relatively low light levels when melting reduces the thickness of
the ice and snow cover. Only after the ice breaks up, when melting releases the ice biota into the water column
and meltwater leads to surface stratification, a major phytoplankton bloom of a few weeks develops, fuelling
the higher trophic foodweb of the Arctic (Gradinger et al., 1999, and literature quoted).
The marginal ice zones, i.e. where the ice gets broken up in warmer Atlantic or Arctic water, therefore play an
important role in the overall production patterns of the Arctic Ocean. Due to the strong water column
stratification and increased light levels involved with the melting of the ice, the location and recession of the
ice edge in spring and summer determines the timing and magnitude of the spring phytoplankton bloom, which
is generally earlier than in the open water (Gradinger and Baumann, 1991; Smith Jr et al., 1987). Wind- or
eddy-induced upwelling in the marginal ice zone, as well as biological regeneration processes replenish the
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surface nutrient pool and therefore prolong the algal growth period (Gradinger and Baumann, 1991; Smith,
1987). The hydrographic variability explains the patchy patterns of primary and secondary production
observed, as well as consequently the patchy occurrence of predators.
The polar front separates to some degree the pelagic faunas of the polar and Arctic waters in the Greenland
Sea and Fram Strait, each characterised by a few dominant copepod species with different life history
strategies (Hirche et al., 1991; see also review in Melle et al., 2005): In polar waters, Calanus glacialis uses
under ice plankton production and lipid reserves for initiating its spring reproduction phase, however depending
on the phytoplankton bloom for raising its offspring (e.g. Leu et al., 2011). Somewhat later, on the warm side
of the polar front in Arctic water, the Atlantic species Calanus finmarchicus uses the ice edge-related
phytoplankton bloom for secondary production. Calanus hyperboreus, the third and largest of the charismatic
copepod species has its core area of distribution in the Arctic waters of the Greenland Sea (Hirche, 1997;
Hirche et al., 2006).
Zooplankton of the Arctic Basin
Overall zooplankton biomass decreases towards the central Arctic basin, reaching a minimum in the most
northerly waters, i.e. the region with permanent ice cover (Mumm et al., 1998). However, investigations in
recent years demonstrated increased biomasses compared to studies several decades earlier - possibly a
consequence of the decrease in ice thickness and cover which only enabled the investigations to take place
from ship board.
There is a south-north decrease in zooplankton biomass, with a sharp decline north of 83°N (Hirche and
Mumm, 1992), coinciding with differences in the species composition of the biomass-forming zooplankton
species. Whereas the southern Nansen basin plankton is dominated by the Atlantic species Calanus
finmarchicus, entering the Arctic Basin with the West Spitsbergen Current, the northernmost branch of the
North Atlantic current, the Arctic and polar species Calanus hyperboreus and C. glacialis dominate the
biomass in the high-Arctic Amundsen and Makarov Basins (Auel and Hagen, 2002; Mumm et al., 1998). The
zooplankton species communities generally can be differentiated according to their occurrence in Polar
Surface Water (0-50 m, temperature below –1.7°C, salinity less than 33.0), Atlantic Layer (200–900 m;
temperature 0.5–1.5°C); salinity 34.5–34.8) and Arctic Deep Water (deeper than 1000 m, temperature -0,5-1° C, salinity > 34.9) (Auel and Hagen, 2002; Grainger, 1989; Kosobokova, 1982). The polar surface
community in the upper 50 m of the water column consists of original polar species as well as species
emerging from deeper Atlantic waters, alltogether leading to a high abundance and biomass peak in summer.
Diversity and biomass are minimal in the impoverished Arctic basin deepwater community (Kosobokova 1982).
Apart from a limited exchange with the Atlantic Ocean via the Fram Strait, the central Arctic deep-sea basins
are isolated from the rest of the world ocean deepsea fauna. Therefore, the bathypelagic fauna consists of a
few endemic Arctic species and some species of Atlantic origin. Due to the separation of the Eurasian and
Canadian Basins by the Lomonosov Ridge, significant differences in hydrographic parameters (Anderson et
al. 1994) and in the zooplankton composition occur between both basins (Auel and Hagen, 2002).
Fish
Polar cod, Boreogadus saida, is a keystone species in the ice-related foodwebs of the Arctic. Due to schooling
behavior and high energy content polar cod efficiently transfer the energy from lower to higher trophic levels,
such as seabirds, seals and some whales (Crawford and Jorgenson, 1993).
Seabirds
Ice cover is a physical feature of major importance to marine birds in high latitude oceans, providing access to
resources, refuge from aquatic predators (Hunt, 1990). As seabirds are dependant on leads between ice floes
or otherwise open water to access food, they search for the most productive waters in polynias (places within
the ice which are permanently ice free) and marginal ice zones (Hunt, 1990). Here they forage both on the
pelagic and sympagic ice-related fauna, especially the early stages of polar cod and the copepods Calanus
hyperboreus and C. glacialis. Likely, they benefit of the structural complexity and good visibility of their prey
near the ice (Hunt, 1990).
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In the Greenland Sea and Fram Strait, major breeding colonies exist on Svalbard, Greenland and on Jan
Mayen, all of these within reach of the seasonally moving marginal ice zone or a polynia (North East Water
Polynia on the East Greenland shelf). Breeding seabirds like Little auks (Alle alle), from colonies in the
northern Svalbard archipelago feed their offspring with prey caught in the vicinity of the nests, however
intermittently travel at least 100 km to the marginal ice zone at 80° N to replenish their body reserves (Jakubas
et al., Online 03 June 2011). Therefore, the distance of the marginal ice zone to the colony site is a critical
factor determining the breeding success (e.g. Joiris and Falck, 2011). Opportunistically, the birds also use
other zooplankton aggregations such as a in a cold core eddy in the Greenland Sea, closer to the nesting site
(Joiris and Falck, 2011).
A synopsis of seabird data for the period 1974–1993 (Joiris, 2000) showed that the little auk is one of the most
abundant species, together with the fulmar Fulmarus glacialis, kittiwake Rissa tridactyla and Brünnich’s
guillemot Uria lomvia in the European Arctic seas (mainly the Norwegian and Greenland Seas). In the
Greenland Sea and the Fram Strait, little auks represented the main species in polar waters, at the ice edge
and in closed pack ice, reaching more than 50% of all bird species (Joiris and Falck, 2011). In spring and
autumn, millions of seabirds pass through the area when migrating between their breeding sites on Svalbard
or the Russian Arctic and their wintering areas in Canada (Gill et al., 2011).
There are several seabird species in the European Arctic which are only met in ice-covered areas, for example
the Ivory gull Pagophila eburnea and the Thick-billed guillemot Uria lomvia (see e.g. CAFF, 2010): Both
species spend the entire year in the Arctic, and breed in close vicinity to sea ice although Thick-billed guillemots
were observed to fly up to 100 km from their colonies over open water to forage at the ice edge (Bradstreet
1979). The relatively rare Ivory gulls are closely associated with pack-ice, favouring areas with 70 – 90% ice
cover near the ice edge, where they feed on small fish, including juvenile Arctic cod, squid, invertebrates,
macro-zooplankton, carrion, offal and animal faeces (e.g. OSPAR Commission, 2009b). Ivory gulls have a low
reproductive rate and breeding only takes place if there is sufficient food, which makes the population highly
vulnerable to the effects of climate warming (e.g. OSPAR Commission, 2009b). Thick-billed guillemots are
relatively long lived and slow to reproduce and has a low resistance to threats including oil pollution, by-catch
in and competition with commercial fisheries operations, population declines due to hunting – particularly in
Greenland (OSPAR Commission, 2009c).
Ivory gull and Thick-billed guillemots are both listed by OSPAR as being under threat and/or decline, (OSPAR
Commission, 2008) and in 2011 recommendations for conservation action were agreed (OSPAR Commission,
2011) which will be implemented in conjunction with the circumpolar conservation actions of CAFF (CAFF,
1996; Gilchrist et al., 2008).
Marine mammals
Several marine mammal species permanently associate with sea ice in the European Arctic. These include
polar bear, walrus, and several seal species: bearded, Erignathus barbatus; ringed, Pusa hispida; hooded,
Cystophora cristata; and harp seal Pagophilus groenlandicus. Three whale species also occupy Arctic waters
year- round – narwhal, Monodon monoceros; beluga whale, Delphinapterus leucas; and bowhead whale,
Balaena mysticetus.
Polar bears Ursus maritimus are highly specialized for and dependent on the sea ice habitat and are therefore
particularly vulnerable to changes in sea ice extent, duration and thickness. They have a circumpolar
distribution limited by the southern extent of sea ice. Three subpopulations of polar bears occur in the European
high Arctic: the East Greenland, Barents Sea and Arctic Basin sub-populations, all with an unknown population
status (CAFF, 2010). Following the young-of-the-year ringed seal distribution, polar bears are most common
close to land and over the shelves, however some also occur in the permanent multi-year pack ice of the
central Arctic basin (Durner et al., 2009). Due to low reproductive rates and long lifetime, it is expected that
the polar bears will not be able to adapt to the current fast warming of the Arctic and become extirpated from
most of their range within the next 100 years (Schliebe et al., 2008).
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Walrusses, Odobenus rosmarus, inhabit the Arctic ice year-round. They are conservative benthic feeders,
diving to 80-100 m depth for scaping off the rich mollusc fauna of the continental shelves, and need ice floes
as resting and nursing platform close to their foraging grounds. Walrusses have been subject to severe hunting
pressure from the end of the 18th century to the mid 20th century, and are still hunted today in Greenland
(NAMMCO). By 1934, the estimated 70000-80000 individuals of the Atlantic population were reduced to 12001300, with none left on Svalbard (Weslawski et al., 2000). Todays relatively small sub-populations on the East
Greenland and Svalbard-Franz Josef Land coasts have recently shown a slightly increasing trend, in the latter
case reflecting the full protection of the species since the 1950´s (CAFF, 2010; NAMMCO). Apart from their
sensitivity to direct human disturbance and pollution, it is expected that walrusses will suffer from the changing
ice conditions (location, thickness for being used as haul-out site) as well as changes in ice-related productivity.
The Atlantic subspecies of the bearded seal, Erignathus barbatus occurs south of 85° N from the central
Canadian Arctic east to the central Eurasian Arctic, but no population estimates exist (Kovacs, 2008b).
Because of their primarily benthic feeding habits they live in ice covered waters overlying the continental shelf.
They are typically found in regions of broken free-floating pack ice; in these areas bearded seals prefer to use
small and medium sized floes, where they haul out no more than a body length from water and they use leads
within shore-fast ice only if suitable pack ice is not available (Kovacs, 2008b, and literature quoted).
The Arctic ringed seal Pusa (Phoca) hispida hispida has a very large population size and broad distribution,
however, there are concerns that future changes of Arctic sea ice will have a negative impact on the
population, some of which have already been documented in some parts of the subspecies range (Kovacs et
al., 2008). As the other seals, the ringed seal uses sea ice exclusively as their breeding, moulting and resting
(haulout) habitat, and feed on small schooling fish and invertebrates. In a co-evolution with one of their main
predators, the polar bear, they developed the ability to create and maintain breathing holes in relatively thick
ice, which makes them well adapted to living in fully ice covered waters allover the year.
The West Ice (or Is Odden) to the west of Jan Mayen, at approx. 72-73° N, in early spring a stretch of more of
less fast drift ice, is of crucial importance as a whelping and moulting area for harp seals and hooded seals
(summarised e.g. by ICES, 2008). Discovered in the early 18th century, up to 350000 seals (1920s) were killed
per year, decimating the populations from an estimated one million individuals in the 1950s (Ronald et al.,
1982) to today´s 70000 and 243000 of hooded and harp seals, respectively (Kovacs, 2008a, c).
Hooded seal, Cystophora cristata, is a pack ice species, which is dependent on ice as a substrate for pupping,
moulting, and resting and as such is vulnerable to reduction in extent or timing of pack ice formation and
retreat, as well as ice edge related changes in productivity (Kovacs, 2008a, and literature quoted). Hooded
Seals feed on a wide variety of fish and invertebrates, including species that occur throughout the water
column. After breeding an moulting on the West Ice they follow the retreating pack ice to the north, but also
spend significant periods of time pelagically, without hauling out (Folkow and Blix 1999) in (Kovacs, 2008a).
The northeast Atlantic breeding stock has declined by 85-90 % over the last 40-60 years. The cause of the
decline is unknown, but very recent data suggests that it is on-going (30% within 8 years), despite the protective
measures that have been taken in the last few years. The species is therefore considered to be vulnerable
(Kovacs, 2008a).
Harp seals Pagophilus (Phoca) groenlandicus are the most numerous seal species in the Arctic seas. Their
reproduction takes place in huge colonies, for example on the pack ice of the ‘‘West Ice’’ north of Jan Mayen,
and after the breeding season they follow the retreating pack ice edge northwards up to 85° N, feeding mainly
on polar cod under the ice (Kovacs, 2008c) .
Narwhals Monodon monoceros primarily inhabit the ice-covered waters of the European Arctic, including the
ice sheet off East Greenland (Jefferson et al., 2008b). For two months in summer, they visit the shallow fjords
of East Greenland, spending all the rest of the year offshore, in deep ice-covered waters along the continental
slope in the Greenland Sea and Arctic Basin (Heide-Jørgensen and Dietz, 1995). Narwhals are deep diving
benthic feeders and forage on fish, squid, and shrimp, especially Arctic fish species, such as Greenland halibut,
Arctic cod, and polar cod at up to 1500 m depth and mostly in winter. A recent assessment of the sensitivity of
ICES Advice 2013, Book 1
125
all Arctic marine mammals to climate change ranked the narwhal as one of the three most sensitive species,
primarily due to its narrow geographic distribution, specialized feeding and habitat choice, and high site fidelity
(Laidre et al. 2008 in (Jefferson et al., 2008b)).
Bowhead whales Balaena mysticetus are found only in Arctic and subarctic regions and a Svalbard-Barents
population occurs from the coast of Greenland across the Greenland Sea to the Russian Arctic. They spend
all of their lives in and near openings in the pack ice feeding on small to medium-sized zooplankton. They
migrate to the high Arctic in summer, and retreat southward in winter with the advancing ice edge (Moore and
Reeves 1993 in (Reilly et al., 2008)). Whaling has decimated the original bowhead whale populations to be
rare nowadays, listed by OSPAR as being under threat and/or decline (OSPAR Commission, 2008). The
species is considered to be very sensitive to changes in the ice-related ecosystem as well as sound
disturbance, possible consequences of a progressive reduction of ice cover (OSPAR Commission, 2009a).
Belugas Delphinapterus leucas prefer coastal and continental shelf waters with a broken-up ice cover. They
have never been surveyed around Svalbard. Pods numbering into the thousands are sighted irregularly around
the archipelago, and pods ranging from a few to a few hundred individuals are seen regularly (Gjertz and Wiig
1994; Kovacs and Lydersen 2006 in (Jefferson et al., 2008a)).
Little is known about the populations of the larger fauna in the Central Arctic Basin over the deepsea basins
and ridges. But it is not likely that it is currently an area of great abundance - too far from the coastal nesting
sites of marine birds, and over too deep water to allow feeding on benthos, as most of the larger mammals
would need, and currently of too low plankton production to feed the large whales. All of these groups have
their distribution center along the continental shelves presently - however, following the receeding ice edge
out to the central Arctic basin may be one of the options for the future.
Feature condition, and future outlook
This high Arctic region is particularly vulnerable to the the loss of ice cover and other effects of the anticipated
global warming, including elevated UV radiation levels (Agustí, 2008). (Wassmann et al., 2010) summarise
what changes may be expected within the subarctic/Arctic region:
•
northward displacement (range shifts) of subarctic and temperate species, and cross-Arctic transport
of organisms;
•
increased abundance and reproductive output of subarctic species, decline and reduced reproductive
success of some Arctic species associated with the ice and species now preyed upon by predators
whose preferred prey have declined;
•
increased growth of some subarctic species and primary producers, and reduced growth and condition
of animals that are bound to, associated with, or born on the ice;
•
anomalous behaviour of ice-bound, ice-associated, or ice-born animals with earlier spring events and
delayed fall events;
•
changes in community structure due to range shifts of predators resulting in changes in the predator–
prey linkages in the trophic network.
(Wassmann, 2008) expects radical changes in the productivity, functional relationships and biodiversity of the
Arctic Ocean. He suggests that a warmer climate with less ice cover will result in greater primary production,
a reduction of the stratified water masses to the south, changes in the relationship between biological
processes in the water column and the sediments, a reduction in niches for higher trophic levels and a
displacement of Arctic by boreal species. On the shelves, increased sediment discharges are expected to
lower the primary production due to higher turbidity, and enhance the organic input to the deep ocean. A more
extensive review of expected or suspected consequences of climate change for the marine system of the Arctic
is given in (Loeng et al., 2005).
Figure 3, extracted from (Gill et al., 2011), presents the conceptual ideas about possible Arctic ecosystem
changes mediated by human impact:
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The normal situation shown in the upper left panel consists of ice-dependent species and species that tolerate
a broader range of temperatures and are found in waters with little or no sea ice. Primary production occurs in
phytoplankton (small dots in the figure) in ice-free waters and in ice-attached algae and phytoplankton in icecovered waters. Phytoplankton (small t-shaped symbols in the figure) and ice algae are the main food sources
for zooplankton and benthic animals. The fish community consists of both pelagic and demersal species.
Several mammals are ice-associated, including polar bears and several species of seals. A number of sea bird
species are also primarily associated with ice-covered waters.
At moderate temperature increases (upper right) populations of ice-dependent species are expected to decline
as sea ice declines, and sub-Arctic species are expected to move northwards. Arctic benthic species are
expected to decline, especially if their distributions are pushed close to or beyond the continental slope.
The expected effects from fisheries relate to the continental shelves. Two major effects are reductions in
populations of benthic organisms due to disturbance from bottom trawling and removal of large individuals in
targeted fish stocks. In addition, the size of targeted stocks, both demersal and pelagic, may be reduced.
In addition, the effects of ocean acidification are considered (lower right). Ocean acidification will result in
depletion of carbonate phases such as aragonite and calcite. This will alter the structure and function of
calcareous organisms, particularly at lower trophic levels. Changes in pH can also alter metabolic processes
in a range of organisms. It is not known how these changes will propagate to higher trophic levels, but the
effects could be substantial.
c.f. Figure 3: Conceptual models showing potential impacts on Arctic marine ecosystems under different
scenarios (Gill et al., 2011).
(Gill et al., 2011) conclude that the central part of the Arctic Basin is not a region for fisheries or oil and gas
exploration. However, this region has played and will continue to play a very important role in the redistribution
of pollutants, due to ice drift and/or currents between coastal and shelf areas and the Arctic Basin peripheries,
far from sources of pollution.
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Assessment against CBD EBSA Criteria
Table 1. relation of each of the CBD criteria to the proposed area relating to the best available science. Note
that a candidate EBSA may qualify on the basis of one or more of the criteria, the boundaries of the EBSA
need not be defined with exact precision.
CBD EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Know
Uniqueness or The area contains either (i) unique (“the only one
rarity
of its kind”), rare (occurs only in few locations) or
endemic species, populations or communities,
and/or (ii) unique, rare or distinct, habitats or
ecosystems; and/or (iii) unique or unusual
geomorphological or oceanographic features
Low
Some
High
x
Explanation for ranking
Arctic sea ice, in particular the multiyear ice of the Central Arctic is globally unique and hosts endemic
species such as the Gammarid amphipod Gammarus wilkitzki and sea ice meiofauna which will disappear
with the melting of the ice. Polar bears, walrusses, bowhead whales, narwhales, belugas, several seal
species and many bird species are endemic to the high Arctic ice.
While sea ice species such as G. wilkitzki are not endemic to the proposed EBSA they are endemic to the
Arctic and unique within the OSPAR area
Special
Areas that are required for a population to
importance for survive and thrive
life-history
stages of
species
x
Explanation for ranking
Sea ice is essential for its sympagic fauna, and to some extent also for the pelagic associated fauna which
also depends on the right timing of biomass production (match/mismatch with bloom periods). The marginal
ice zone and other openings in the ice are essential feeding grounds for a large number of ice-associated
species which exploit the seasonallly high production there.
At present the area covered by the proposed EBSA is ice-covered throughout the summer but although
there is no marginal ice zone there will be an ice zone community present, thus the sea ice is essential to
maintain the sympagic biological community and associated ecosystem functions.
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Importance for
threatened,
endangered or
declining
species and/or
habitats
Area containing habitat for the survival and
recovery of endangered, threatened, declining
species or area with significant assemblages of
such species
x
Explanation for ranking
The high arctic ice hosts endemic species such as the Gammarid amphipod Gammarus wilkitzki and sea ice
meiofauna which will disappear with the melting of the ice. Many of the obligatory ice-related species are
listed as vulnerable by IUCN, and/or listed as under threat and/or decline by OSPAR, examples include the
Ivory gull, thick-billed guillemot, bowhead whale, hooded seal and polar bear. With the overall trend of
retreating sea ice extent, the proposed EBSA may become increasingly important for all ice-dependent
species in the future.
Vulnerability,
fragility,
sensitivity, or
slow recovery
Areas that contain a relatively high proportion of
sensitive habitats, biotopes or species that are
functionally fragile (highly susceptible to
degradation or depletion by human activity or by
natural events) or with slow recovery
x
Explanation for ranking
The ice-related foodweb and ecosystem is highly sensitive to the ecological consequences of a warming
climate. Beyond this the Arctic is at the forefront of the impacts of ocean acidification (Wicks & Roberts
2012). The largest changes in ocean pH will occur in the Arctic Ocean, with complete undersaturation of the
Arctic Ocean water column predicted before the end of this century (Steinacher et al. 2009). Many of the
seabird and mammal populations are particularly sensitive to changes due to their already low population
numbers, and low fertility. If the retreat of the ice to the north will lead to increased shipping and oil and gas
exploitation in Arctic waters, the increased risk of spills would also pose a potential hazard for example for
guillemots, which are extremely susceptible to mortality from oil pollution (CAFF, 2010). In addition, some
species like Ivory gull are sensitive to an increased heavy metal load in their prey.
Biological
productivity
Area containing species, populations or
communities with comparatively higher natural
biological productivity
Explanation for ranking
This criterion was not evaluated in the OSPAR/NEAFC/CBD Workshop. ICES did not have enough
information to evaluate this criterion.
Biological
diversity
Area contains comparatively higher diversity of
ecosystems, habitats, communities, or species,
or has higher genetic diversity
ICES Advice 2013, Book 1
129
Explanation for ranking
This criterion was not evaluated in the OSPAR/NEAFC/CBD Workshop. ICES did not have enough
information to evaluate this criterion.
References
Aagaard, K., 1989. A synthesis of Arctic Ocean circulation. Rapport Proces et Verbeaux Réunion du Conseil
international pour l'Exploration de la Mer 188, 11-22.
Aagaard, K., Coachman, L.K., 1968. The East Greenland Current north of Denmark Strait: Part II. Arctic 21,
267-290.
Aagaard, K., Swift, J.H., Carmack, E.C., 1985. Thermohaline circulation in the Arctic mediterranean seas.
Journal of Geophysical Research 90, 4833-4846.
Agustí, S., 2008. Impacts of increasing ultraviolet radiation on the polar oceans. In: Impacts of global
warming on polar ecosystems. Duarte, C.M. (Ed.) Fundación BBVA pp. 25-46.
Anderson, L.G., Jones, E.P., Koltermann, K.P., Schlosser, P., Swift, J.H., Wallace, D.W.R., 1989. The first
oceanographic section across the Nansen Basin in the Arctic Ocean. Deep Sea Research 36, 475482.
Angelen, J.H.v., Broeke, M.R.v.d., Kwok, R., 2011. The Greenland Sea Jet: A mechanism for wind‐driven
sea ice export through Fram Strait. Geophysical Research Letters 38 (L12805).
Anisimov, O.A., Vaughan, D.G., Callaghan, T.V., Furgal, C., Marchant, H., Prowse, T.D., Vilhjálmsson, H.,
Walsh, J.E., 2007. Polar regions (Arctic and Antarctic). In: Climate Change 2007: Impacts, Adaptation
and Vulnerability. Contribution of Working Group II to the Fourth Assessment Report of the
Intergovernmental Panel on Climate Change. Parry, M.L., Canziani, O.F., Palutikof, J.P., Linden,
P.J.v.d., Hanson, C.E. (Eds.)Cambridge University Press, Cambridge pp. 653-685.
Arndt, C., E. , Pavlova, O., 2005. Origin and fate of ice fauna in the Fram Strait and Svalbard area. Marine
Ecology Progress Series 301, 55-66.
Auel, H., Hagen, W., 2002. Mesozooplankton community structure, abundance and biomass in the central
Arctic Ocean. Marine Biology 140, 1013-1021.
Bluhm, B.A., Gebruk, A.V., Gradinger, R., Hopcroft, R.R., Huettmann, F., Kosobokova, K.N., Sirenko, B.I.,
Weslawski, J.M., 2011. Arctic marine biodiversity: An update of species richness and examples of
biodiversity change. Oceanography 24 (3), 232-248.
Bradstreet, M.S.M., Cross, W.E., 1982. Trophic relationships at high Arctic ice edges. Arctic 35 (1), 1-12.
CAFF, 1996. International Murre conservation strategy and action plan. CAFF International Secretariat,
CAFF Circumpolar Seabird Working Group, Akureyri, Iceland, pp. 1-16.
CAFF, 2010. Arctic Biodiversity Trends 2010. Selected indicators of change. CAFF International Secretariat,
, Akureyri, Iceland.
Carey, A.G.I., 1985. Marine Ice Fauna. In: Arctic Sea Ice Biota. A., H.R. (Ed.)CRC Press, Boca Raton.
Florida pp. 17-190
Crawford, R.E., Jorgenson, J.K., 1993. Schooling behaviour of arctic cod, Boreogadus saida in relation to
drifting pack ice. Environmental Biology of Fishes 36 (4), 345-357.
Durner, G.M., Douglas, D.C., Nielson, R.M., Amstrup, S.C., McDonald, T.L., Stirling, I., Mauritzen, M., Born,
E.W., Wiig, Ø., Deweaver, E., Serreze, M.C., Belikov, S.E., Holland, M.M., Maslanik, J., Aars, J.,
130
ICES Advice 2013, Book 1
Bailey, D.A., Derocher, A.E., 2009. Predicting 21st-century polar bear habitat distribution from global
climate models. Ecological Monographs 79 (1), 25-58.
Edmonds, H.N., Michael, P.J., Baker, E.T., Connelly, D.P., Snow, J.E., Langmuir, C.H., Dick, H.J.B., Mühe,
R., German, C.R., Graham, D.W., 2003. Discovery of abundant hydrothermal venting on the ultraslowspreading Gakkel ridge in the Arctic Ocean. Nature 421, 252-256.
Gilchrist, G., Strøm, H., Gavrilo, M.V., Mosbech, A., 2008. International Ivory Gull conservation strategy and
action plan. CAFF International Secretariat, Circumpolar Seabird Group (CBird). CAFF Technical
Report No. 18.
Gill, M.J., Crane, K., Hindrum, R., Arneberg, P., Bysveen, I., Denisenko, N.V., Gofman, V., Grant-Friedman,
A., Gudmundsson, G., Hopcroft, R.R., Iken, K., Labansen, A., Liubina, O.S., Melnikov, I.A., Moore,
S.E., Reist, J.D., Sirenko, B.I., Stow, J., Ugarte, F., Vongraven, D., Watkins, J., 2011. Arctic Marine
Biodiversity Monitoring Plan (CBMP-MARINE PLAN), CAFF Monitoring Series Report No.3, April
2011. CAFF International Secretariat,, Akureyri, Iceland.
Gradinger, R., 1995. Climate change and biological oceanography of the Arctic Ocean. Phil. Trans. R. Soc.
A 352, 277-286.
Gradinger, R., Bluhm, B.A., 2004. In situ observations on the distribution and behavior of amphipods and
Arctic cod (Boreogadus saida) under the sea ice of the high Arctic Canadian Basin. Polar Biology 27,
595-603.
Gradinger, R., Friedrich, C., Spindler, M., 1999. Abundance, biomass and composition of the sea ice biota of
the Greenland Sea pack ice. Deep Sea Research 46, 1457-1472.
Gradinger, R., Spindler, M., Henschel, D., 1991. Development o Arctic sea-ice organisms under graded
snow cover. In: Proceedings of the Pro Mare Symposium on Polar Marine Ecology. Sakshaug, E., E.,
H.C.C., Øritsland, N.A. (Eds.), Polar Research 10 (1), Trondheim pp. 295-307.
Gradinger, R.R., Baumann, M.E.M., 1991. Distribution of phytoplankton communities in relation to the largescale hydrographical regime in the Fram Strait. Mar. Biol. 111, 311-321.
Grainger, E.H., 1989. Vertical distribution of zooplankton in the central Arctic Ocean. In: Proc 6th Conf
Comite´Arctique Int 1985. Rey, L., Alexander, V. (Eds.) Brill Leiden pp. 48–60.
Heide-Jørgensen, M.P., Dietz, R., 1995. Some characteristics of narwhal, Monodon monoceros, diving
behaviour in Baffin Bay. Canadian Journal of Zoology 73, 2106-2119.
Hirche, H.J., 1997. Life cycle of the copepod Calanus hyperboreus in the Greenland Sea. Marine Biology
128 (4), 607-618.
Hirche, H.J., Baumann, M.E.M., Kattner, G., Gradinger, R., 1991. Plankton distribution and the impact of
copepod grazing on primary production in Fram Strait, Greenland Sea. Journal of Marine Systems 2
(3-4), 477-494.
Hirche, H.J., Mumm, N., 1992. Distribution of dominant copepods in the Nansen Basin, Arctic Ocean, in
summer. Deep Sea Research Part A. Oceanographic Research Papers 39 (2, Part 1), S485-S505.
Hirche, H.J., Muyakshin, S., Klages, M., Auel, H., 2006. Aggregation of the Arctic copepod Calanus
hyperboreus over the ocean floor of the Greenland Sea. Deep Sea Research Part I: Oceanographic
Research Papers 53 (2), 310-320.
Horner, R., Ackley, S.F., Dieckmann, G.S., Gulliksen, B., Hoshiai, T., Legendre, L., Melnikov, I.A., Reeburgh,
W.S., Spindler, M., Sullivan, C.W., 1992. Ecology of sea ice biota. Habitat, terminology, and
methodology. Polar Biology 12 (3), 417-427.
Hunt, G.L.J., 1990. The pelagic distribution of marine birds in a heterogeneous environment. Polar Research
8, 43-54.
ICES, 2008. Report of the ICES Advisory Committee In: ICES Advice, Book 3, The Barents and the
Norwegian SEa.
ICES Advice 2013, Book 1
131
Jakubas, D., Iliszko, L., Wojczulanis-Jakubas, K., Stempniewicz, L., Online 03 June 2011. Foraging by little
auks in the distant marginal sea ice zone during the chick-rearing period. Polar Biology, 1-9.
Jefferson, T.A., Karczmarski, L., Laidre, K., O’Corry-Crowe, G., Reeves, R.R., Rojas-Bracho, L., Secchi,
E.R., Slooten, E., Smith, B.D., Wang, J.Y., Zhou, K., 2008a. Delphinapterus leucas In: IUCN 2011.
IUCN Red List of Threatened Species. Version 2011.1. www.iucnredlist.org Downloaded on 31
August 2011.
Jefferson, T.A., Karczmarski, L., Laidre, K., O’Corry-Crowe, G., Reeves, R.R., Rojas-Bracho, L., Secchi,
E.R., Slooten, E., Smith, B.D., Wang, J.Y., Zhou, K., 2008b. Monodon monoceros. In: IUCN 2011.
IUCN Red List of Threatened Species. Version 2011.1. . www.iucnredlist.org Downloaded on 31
August 2011.
Joiris, C., Falck, E., 2011. Summer at-sea distribution of little auks Alle alle and harp seals Pagophilus
(Phoca) groenlandica in the Fram Strait and the Greenland Sea: impact of small-scale hydrological
events. Polar Biology 34 (4), 541-548.
Joiris, C.R., 2000. Summer at-sea distribution of seabirds and marine mammals in polar ecosystems: a
comparison between the European Arctic seas and the Weddell Sea, Antarctica. Journal of Marine
Systems 27, 267-276.
Klitgaard, A.B., Tendal, O.S., 2004. Distribution and species composition of mass occurrences of large-sized
sponges in the northeast Atlantic. Progress in Oceanography 61, 57-98.
Kosobokova, K.N., 1982. Composition and distribution of the biomass of zooplankton in the central Arctic
Basin. Oceanology 22, 744-750.
Kovacs, K., 2008a. Cystophora cristata. IUCN 2011. IUCN Red List of Threatened Species. Version 2011.1.
www.iucnredlist.org Downloaded on 31 August 2011.
Kovacs, K., 2008b. Erignathus barbatus. IUCN 2011. IUCN Red List of Threatened Species. Version 2011.1.
www.iucnredlist.org Downloaded on 31 August 2011.
Kovacs, K., 2008c. Pagophilus groenlandicus. IUCN 2011. IUCN Red List of Threatened Species. Version
2011.1. www.iucnredlist.org Downloaded on 31 August 2011.
Kovacs, K., Lowry, L., Härkönen, T., 2008. Pusa hispida. In: IUCN 2011. IUCN Red List of Threatened
Species. Version 2011.1. . www.iucnredlist.org Downloaded on 31 August 2011.
Kwok, R., 2009. Outflow of Arctic Ocean sea ice into the Greenland and Barents seas: 1979-2007. Journal of
Climate 22, 2438-2456.
Legendre, L., Ackley, S.F., Dieckmann, G.S., Gulliksen, B., Horner, R., Hoshiai, T., Melnikov, I.A., Reeburgh,
W.S., Spindler, M., Sullivan, C.W., 1992. Ecology of sea ice biota. Polar Biology 12 (3), 429-444.
Leu, E., Søreide, J.E., Hessen, D.O., Falk-Petersen, S., Berge, J., 2011. Consequences of changing sea ice
cover for primary and secondary producers in the European Arctic shelf seas: timing, quantity, and
quality. Progress in Oceanography 90, 18-32.
Loeng, H., Brander, K., Carmack, E.C., Denisenko, S., Drinkwater, K., Hansen, B., Kovacs, K., Livingston,
P., McLaughlin, F., Sakshaug, E., 2005. Marine systems. In: Arctic Climate Impact Assessment,
ACIA. Symon, C., Arrisand, L., Heal, B. (Eds.),Cambridge University Press, Cambridge pp. 453-538.
Mauritzen, C., Hansen, E., Andersson, M., Berx, B., Beszczynska-Möller, A., Burud, I., Christensen, K.H.,
Debernard, J., de Steur, L., Dodd, P., Gerland, S., Godøy, Ø., Hansen, B., Hudson, S., Høydalsvik, F.,
Ingvaldsen, R., Isachsen, P.E., Kasajima, Y., Koszalka, I., Kovacs, K.M., Køltzow, M., LaCasce, J.,
Lee, C.M., Lavergne, T., Lydersen, C., Nicolaus, M., Nilsen, F., Nøst, O.A., Orvik, K.A., Reigstad, M.,
Schyberg, H., Seuthe, L., Skagseth, Ø., Skar∂hamar, J., Skogseth, R., Sperrevik, A., Svensen, C.,
Søiland, H., Teigen, S.H., Tverberg, V., Wexels Riser, C., 2011. Closing the loop - Approaches to
monitoring the state of the Arctic Mediterranean during the International Polar Year 2007-2008.
Progress in Oceanography 90 (1-4), 62-89.
132
ICES Advice 2013, Book 1
Maykut, G.A., 1985. The ice environment. In: Sea-ice biota. Horner, R. (Ed.)CRC Press, Boca Raton pp. 2182.
Melle, W., Ellertsen, B., Skjoldal, H.R., 2005. Zooplankton: The link to higher trophic levels. In: The Nordic
Seas: An integrated perspective oceanography, climatology, biogeochemistry, and modelling. .
Drange, H., Dokken, T., Furevik, T., Gerdes, R., Berger, W. (Eds.)Geophysical Monograph Series 158
pp. 137-202.
Mumm, N., Auel, H., Hanssen, H., Hagen, W., Richter, C., Hirche, H.J., 1998. Breaking the ice: large-scale
distribution of mesozooplankton after a decade of Arctic and transpolar cruises. Polar Biology 20 (3),
189-197.
NAMMCO, The Atlantic Walrus. North Atlantic Marine Mammal Commission. Status of Marine Mammals in
the North Atlantic, Tromsø, pp. 1-7.
OSPAR Commission, 2008. OSPAR List of Threatened and/or Declining Species andHabitats. Reference
number 2008-6. http://www.ospar.org/documents/dbase/decrecs/agreements/0806e_ospar%20list%20species%20and%20habitats.doc.
OSPAR Commission, 2009a. Background Document for Bowhead whale Balaena mysticetus. OSPAR
Commission, Biodiversity Series 494/2010, pp. 1-20.
OSPAR Commission, 2009b. Background Document for Ivory gull Pagophila eburnea. OSPAR Commission,
Biodiversity Series 410/2009, pp. 1-16.
OSPAR Commission, 2009c. Background Document for Thick-billed murre Uria lomvia. OSPAR
Commission, Biodiversity Series 416/2009, pp. 1-20.
OSPAR Commission, 2011. Meeting of the OSPAR Commission (OSPAR) London: 20-24 June 2011.
Summary Record OSPAR 11/20/1-E. OSPAR Commission, London.
Paquette, R., Bourke, R., Newton, J., Perdue, W., 1985. The East Greenland Polar Front in autumn. Journal
of Geophysical Research 90 (C3), 4866-4882.
Piepenburg, D., 2005. Recent research on Arctic benthos: common notions need to be revised. Polar
Biology 28 (10), 733-755.
Reilly, S.B., Bannister, J.L., Best, P.B., Brown, M., , Brownell Jr., R.L., Butterworth, D.S., Clapham, P.J.,
Cooke, J., Donovan, G.P., Urbán, J., Zerbini, A.N., 2008. Balaena mysticetus. In: IUCN 2011. IUCN
Red List of Threatened Species. Version 2011.1. . www.iucnredlist.org Downloaded on 31 August
2011.
Renaud, P.E., Caroll, M.L., Ambrose, W.G.J., 2008. Effects of global warming on Arctic seafloor communities
and its consequences for higher trophic levels. In: Impacts of global warming on polar ecosystems.
Duarte, C.M. (Ed.)Fundación BBVA pp. 141-177.
Rey, F., 2004. Phytoplankton: the grass of the sea. In: The Norwegian Sea Ecosystem. Skjoldal, H.R.
(Ed.)Tapir Academic Press, Trondheim, Norway pp. 97-136.
Ronald, K., Healey, P.J., Fisher, H.D., 1982. The harp seal, Pagophilus groenlandicus. In: Small cetaceans,
seals, sirenians and otters. FAO Fisheries Series No. 5, Vol. IV, Food and Agriculture Organisation of
the United Nations. Workding Party on Mammals.
Schliebe, S., Wiig, Ø., Derocher, A.E., Lunn, N., 2008. Ursus maritimus. In: IUCN 2011. IUCN Red List of
Threatened Species. Version 2011.1. www.iucnredlist.org Downloaded on 31 August 2011.
Smith Jr, W.O., Barber, D., 2007. Polynyas and climate change: a view to the future. In: Polynays, windows
to the world. Halpern, D. (Ed.), Elsevier Oceanography Serie 74, Elsevier, Amsterdam pp. 411-420.
Smith Jr, W.O., Baumann, M.E.M., Wilson, D.L., Aletsee, L., 1987. Phytoplankton biomass and productivity
in the Marginal Ice Zone of the Fram Strait during summer 1984. Journal of Geophysical Research 92
(C7), 6777-6786.
ICES Advice 2013, Book 1
133
Smith, W.O.J., 1987. Phytoplankton dynamics in the marginal ice zones. Oceanography and Marine Biology
Annual Review 25, 11-38.
Smith, W.O.J., Sakshaug, E., 1990. Polar phytoplankton. In: Polar oceanography. Part B. Chemistry, biology
and geology. Smith Jr, W.O. (Ed.) Academic Press, San Diego pp. 477-525.
Steinacher, M., Joos, F., Frölicher, T., Plattner, G. & Doney, S.c. 2009. Imminent ocean acidification in the
Arctic projected with the NcAR global coupled carbon cycle-climate model. Biogeosciences 6, 515–
533.
Süfke, L., Piepenburg, D., Dorrien, C.C.v., 1998. Body size, sex ratio and diet composition of Arctogadus
glacialis (Peters, 1874) (Pisces: Gadidae) in the Northeast Water Polynya (Greenland). Polar Biology
20, 357-363.
Wadhams, P., 1981. The ice cover in the Greenland and Norwegian Seas. Rev. Geophys. Space Physics
19, 345-393.
Wassmann, P., 2008. Impacts of global warming on Arctic pelagic ecosystems and processes. In: Impacts
of global warming on polar ecosystems. Duarte, C.M. (Ed.)Fundación BBVA pp. 113-148.
Wassmann, P., 2011. Arctic marine ecosystems in an era of rapid climate change. Progress in
Oceanography 90, 1-17.
Wassmann, P., Duarte, C.M., Agustí, S., Seijr, M., 2010. Footprints of climate change in the Arctic Marine
Ecosystem. Biological Global Change.
Weslawski, J.M., Hacquebord, L., Stempniewicz, L., Malinga, M., 2000. Greenland whales and walruses in
the Svalbard food web before and after exploitation. Oceanologia 42 (1), 37-56.
Wheeler, P.A., Gosselin, M., Sherr, E., Thibault, D., Kirchman, D.L., Benner, R., Whitledge, T.E., 1996.
Active cycling of organic carbon in the central Arctic Ocean. Nature 380, 697-699.
Wicks, L., Roberts, J.M. (2012) Benthic invertebrates in a high CO2 world. Oceanography & Marine Biology:
An Annual Review 50: 127 -188
Maps and Figures
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Figure 1: Location of the Ecologically or biologically significant areas (EBSA) proposed by WWF in
September 2011. The position of the Arctic and polar fronts was redrawn after (Rey, 2004, Fig. 5.7).
ICES Advice 2013, Book 1
135
Figure 2: Modelled ice age distribution in 1985-2000 (left) compared to February 2008 (right) (CAFF, 2010).
Figure 3: Conceptual models showing potential impacts on Arctic marine ecosystems under different
scenarios (Gill et al., 2011).
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ICES Advice 2013, Book 1
1.5.5.6
Special request, Advice June 2013
ECOREGION
SUBJECT
General advice
OSPAR/NEAFC special request on existing and potential new management
measures for ecologically and biologically significant areas (EBSAs)
Advice summary
ICES provides a summary of management measures already implemented within ecologically and biologically significant
areas (EBSAs). ICES notes that there are numerous measures already in place by both NEAFC and by OSPAR (as requests
to Contracting Parties) and by other competent management authorities, and that both generic and targeted management
measures may offer protection to the features that would qualify as meeting EBSA criteria. The performance of these
measures has not been evaluated and it was not possible to assess whether these measures are sufficient to protect all of
the features that would qualify under EBSA criteria from all potential threats, or whether further measures are required.
ICES notes that some specific areas may need further protective measures.
Request
c) For the use of OSPAR and NEAFC Contracting Parties, as appropriate, provide a separate document with additional
relevant information and up-to-date accounts of the relevant management measures already implemented within the
individual EBSAs.
d) In a separate document, describe potential new management measures within individual EBSAs if appropriate.
ICES advice
ICES summarized the existing management measures or recommendations of bodies with regulatory or coordinating
authority for the major sectoral activities in the OSPAR and NEAFC areas, and, where they exist, those of the authorities
for conservation and protection of special components of biodiversity. Some of the measures apply directly, while others
require implementing legislation by national authorities (or in some cases by the EU). The power to require vessels to
operate in specified ways lies with the Flag State of each vessel.
ICES does not have information on the performance of many of the existing measures, and consequently has not been
able to evaluate whether these management measures would be sufficient to protect all of the features that would qualify
under EBSA criteria from all potential threats. Nonetheless a range of generic and spatially targeted protective
management measures already exist within the EBSA areas. There are, however, some exceptions that may need improved
protective measures:
•
•
•
Josephine Seamount
The Hatton–Rockall basin
The existing fishing areas that lie north of the Azores on the Mid-Atlantic Ridge. One of these is a potential
threat to hydrothermal vents in the area.
ICES advises that a systematic review of the performance of the existing measures and how they interact to reduce threats
to EBSAs is needed before any new management measures could be sensibly considered through a gap analysis. ICES
makes the following general suggestions that are likely to improve the protection of EBSAs in the Northeast Atlantic:
•
•
•
•
Protective measures for vulnerable marine ecosystems (VMEs) should be made permanent. In many cases these
measures are only temporary. This is not appropriate for the long-lived, sessile organisms within VMEs.
Accessibility of existing ecological and fisheries data should be improved through a concerted effort between
relevant authorities.
Coordination of competent authorities should be improved in the selection and adoption of measures in order to
help ensure efficient implementation.
Observer coverage of fishing vessels operating within EBSAs should be increased.
Management measures
North-East Atlantic Fisheries Commission (NEAFC)
Table 1.5.6.6.1 summarizes NEAFC regulations for fishing activities within nine of the ten proposed EBSAs. The Arctic
ice habitat lies outside the regulatory area of NEAFC. The ten proposed EBSA areas are shown in Figure 1.5.6.6.1,
together with existing bottom fisheries closures enforced by NEAFC and high seas MPAs established by OSPAR. Since
ICES Advice 2013, Book 1
137
2005, NEAFC has closed 14 areas to bottom fishing to protect VMEs. In addition (for fisheries management rather than
VME protection), NEAFC has closed an area for haddock on Rockall Bank since 2001 and enforced a seasonal closed
area on the Reykjanes Ridge to protect a blue ling spawning ground. In total the area closed to protect VMEs is in excess
of 600 000 square kilometres and covers all areas where the presence of VMEs have been validated up to the end of 2012.
ICES has recently provided further advice on the boundaries of some of these VMEs (ICES, 2013a).
NEAFC has different bottom-fishing regulations for existing fisheries areas and new fishing areas. Five of the proposed
EBSAs are covered by the ‘New Fishing Area’ regulations only. Exploratory fishing in new areas is only authorized under
strict conditions that include full observer coverage. There have been no applications for exploratory fishing since the
regulations were adopted. Several points are notable:
•
•
All the NEAFC closures lie within the proposed EBSAs.
The majority of the overall area covered by the ten proposed EBSAs is classed by NEAFC as ‘new fishing areas’
and thus subject to strict regulation. Exceptions that are not ‘new fishing areas’ include an existing fishing area
within the proposed EBSA 1 (Reykjanes Ridge), four within the proposed EBSA 3 (Mid-Atlantic Ridge north
of Azores), and a further four within the proposed EBSA 4 (Hatton–Rockall area).
The four major fisheries in the NEAFC Regulatory Area (herring, mackerel, blue whiting, and redfish) are pelagic trawl
fisheries and therefore unlikely to pose threats to seabirds, taxa on the OSPAR list of threatened and declining species, or
VMEs. In addition NEAFC regulations include:
•
•
138
A ban on the use of gillnet at depths greater than 200 m.
A ban on directed fisheries for 17 different species of deep-sea sharks.
ICES Advice 2013, Book 1
Figure 1.5.6.6.1
Map of the southern NEAFC Regulatory Area showing proposed EBSAs (Grey polygons; 1 = Reykjanes Ridge,
2 = Charlie-Gibbs Fracture Zone and Subpolar Frontal Zone, 3 = Mid-Atlantic Ridge north of the Azores, 4 =
Hatton–Rockall Plateau, 5 = Pedro Nunes and Hugo de Lacerda Seamounts, 6 = Northeast Azores–Biscay Rise,
7 = Evlanov Seamount, 8 = West of Azores). Existing NEAFC fishing areas are shown in white, NEAFC bottom
fishery closures in pink, and OSPAR High Seas MPAs in green.
ICES Advice 2013, Book 1
139
Table 1.5.6.6.1
Management measures adopted by NEAFC in each proposed EBSA.
NEAFC closed areas or
Rationale for NEAFC
fishing regulations in the
management measure
proposed area
Area 1. Reykjanes Ridge south of Iceland EEZ
1) Northern Mid-Atlantic
1,3,5) Protection of VME
Ridge (MAR)1
(cold-water corals).
2) Seasonal blue ling
2) Protection for
closure 2
spawning/aggregation
3)Existing fishing areas1
areas of blue ling.
4)New fishing areas1
NEAFC management regulations
1) Area closed to bottom trawling and fishing with static
gear, including bottom-set gillnets and longlines 2009–
2015.
2) This area is closed for fishing blue ling from 15
February to 15 April until 2016.
3) Deep-sea demersal fisheries regulations: Certain gears
are banned (gillnets) and actions against ghost fishing
and lost gear are in place.
4) Authorization to go to new fishing areas follows a
strict exploratory fishing protocol.
Area 2. Charlie-Gibbs Fracture Zone and Subpolar Frontal Zone of the Mid-Atlantic Ridge
Middle MAR1
Protection of VME (coldArea closed to bottom trawling and fishing with static
water corals).
gear, including bottom set gillnets and long-lines 20092015, including Charlie-Gibbs Fracture Zone and the
Subpolar frontal zone.
Area 3. Mid-Atlantic Ridge north of the Azores
1)Southern MAR; Altair
Protection of VME (cold1) Area closed to bottom trawling and fishing with static
Seamount, Antialtair
water corals).
gear, including bottom-set gillnets and longlines 2009–
Seamount1
2015.
2)Existing fishing areas1
2) Deep-sea demersal fisheries regulations: Certain gears
3)New fishing areas1
are banned (gillnets) and actions against ghost fishing
and lost gear are in place.
3) Authorization to go to new fishing areas follows a
strict exploratory fishing protocol.
Area 4. The Hatton and Rockall banks and Hatton–Rockall Basin
1) Rockall Haddock Box3
1) Haddock Box closed to
1) NEAFC has banned bottom trawling in this area.
2) Hatton4
protect juvenile haddock.
2–7) Area closed to bottom trawling and fishing with
2–7) Protection of VME
3) West Rockall Mounds
static gear, including bottom-set gillnets and longlines
(corals, coral reefs, and
closure4
until 2015.
4) NW Rockall closure4
sponge grounds).
8) Deep-sea demersal fisheries regulations: Certain gears
5) SW Rockall closure4
7) Geomorphology.
are banned (gillnets) and actions against ghost fishing
6) Logachev Mounds
and lost gear are in place.
closure 4
9) Authorization to go to new fishing areas follows a
7) Edora Bank closure5
strict exploratory fishing protocol.
8) Existing fishing areas1
9) New fishing areas1
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ICES Advice 2013, Book 1
NEAFC closed areas or
Rationale for NEAFC
NEAFC management regulations
fishing regulations in the
management measure
proposed area
Area 5. Around Pedro Nunes and Hugo de Lacerda Seamounts – IBA MAO3
Area 6. Northeast Azores–Biscay Rise – IBA MAO3
Area 7. Evlanov Seamount Region
Area 8. Northwest of Azores EEZ
Area 9. The Arctic Front – Greenland/Norwegian Seas
New fishing areas1
In most instances there is not enough research or
Observers shall collect data in
data to identify VMEs in “new fishing areas”. To
accordance with a Vulnerable
reduce risks to VMEs to a minimum these areas
Marine Ecosystem Data
are closed to normal commercial bottom fisheries
Collection Protocol.
under normal authorizations to fish from the
Contracting Parties of NEAFC.
Exploratory Bottom Fisheries Protocol. Vessels
authorized under this protocol must have an
observer on board.
Exploratory fishing provides an opportunity to
gather additional data on benthos and fish
communities using industry vessels, and under
strict controls on fishing.
Area 10. The Arctic Ice habitat – multiyear ice, seasonal ice, and marginal ice zone
This proposed area is outside of the NEAFC Regulatory Area.
The following measures can be found at http://neafc.org/measures:
1
2
3
4
5
Rec. na 2011 on regulating bottom fishing as amended by Rec. 12 2013.
Rec. 05 2013 Blue Ling seasonal closure.
Rec. 03 2013 Rockall Haddock.
Rec. 09 2013 Rockall Hatton VME closures.
Rec. 08 2013 Edora Bank VME closure.
International Commission for the Conservation of Atlantic Tuna (ICCAT)
ICCAT has recommendations to mitigate the bycatch of seabirds, turtles, and pelagic shark species, but there are no
specific spatial management measures relevant to the proposed EBSAs.
OSPAR
A range of measures have been adopted by the OSPAR Commission within the proposed EBSAs. These include legally
binding decisions, which have been used for the establishment of seven marine protected areas (MPAs) in areas beyond
national jurisdiction. Five of these lie within the proposed EBSAs. Two others lie outside the proposed EBSAs: the Milne
Seamount complex MPA in the southwest of the OSPAR Area and the Josephine Seamount High Seas MPA in the
southeast (Figure 1.5.6.6.1). For each MPA, OSPAR has also agreed recommendations for their management calling on
Contracting Parties to undertake certain management actions within the competence of OSPAR (Table 1.5.6.6.2).
In addition to these are three types of measures that are not spatially explicit and that apply across the OSPAR maritime
area in the Northeast Atlantic (Table 1.5.6.6.3). These include a series of recommendations for the protection and
conservation of threatened and/or declining species; a recommendation calling on Contracting Parties to specifically take
into account OSPAR’s Listed of species and habitats in the conduct of Environmental Impact Assessments; as well as a
code of conduct for undertaking marine research.
ICES Advice 2013, Book 1
141
Table 1.5.6.6.2
Measures adopted by the OSPAR Commission specific to proposed EBSAs.
Proposed area meeting
the EBSA criteria
Charlie-Gibbs Fracture
Zone and Subpolar
Frontal Zone of the MidAtlantic Ridge
Mid-Atlantic Ridge north
of the Azores
Table 1.5.6.6.3
•
•
•
•
•
•
•
•
•
•
•
•
Spatial management measures in place for specific sub-areas within the proposed
EBSA
(1.a) OSPAR Decision 2010/2 on the establishment of the Charlie-Gibbs South MPA
(1.b) OSPAR Recommendation 2010/13 on the management of the Charlie-Gibbs
South MPA
(2.a) OSPAR Decision 2012/1 on the establishment of the Charlie-Gibbs North High
Seas MPA
(2.b) OSPAR Recommendation 2012/1 on the management of the Charlie-Gibbs North
High Seas MPA
(1.a) OSPAR Decision 2010/6 on the establishment of the Mid-Atlantic Ridge north of
the Azores High Seas MPA
(1.b) OSPAR Recommendation 2010/17 on the management of the Mid-Atlantic Ridge
north of the Azores High Seas MPA
(2.a) OSPAR Decision 2010/3 on the establishment of the Altair Seamount High Seas
MPA
(2.b) OSPAR Recommendation 2010/14 on the management of the Altair Seamount
High Seas MPA
(3.a) OSPAR Decision 2010/4 on the establishment of the Antialtair Seamount High
Seas MPA
(3.b) OSPAR Recommendation 2010/15 on the management of the Antialtair Seamount
High Seas MPA
General management measures taken by the OSPAR Commission that are common to all proposed EBSAs.
OSPAR Code of Conduct for Responsible Marine Research in the Deep Seas and High Seas of the OSPAR
Maritime Area (Reference number: 2008-1)
OSPAR Recommendation 2010/5 on assessments of environmental impact in relation to threatened and/or
declining species and habitats
OSPAR Recommendation 2010/6 on furthering the protection and restoration of the common skate species
complex, the white skate, the angel shark, and the basking shark in the OSPAR Maritime Area
OSPAR Recommendation 2010/7 on furthering the protection and restoration of the Orange roughy
(Hoplostethus atlanticus) in the OSPAR Maritime Area
OSPAR Recommendation 2010/8 on furthering the protection and restoration of Lophelia pertusa reefs in the
OSPAR Maritime Area
OSPAR Recommendation 2010/9 on furthering the protection and restoration of coral gardens in the OSPAR
Maritime Area
OSPAR Recommendation 2011/2 on furthering the protection and conservation of the Ivory gull (Pagophila
eburnea)
OSPAR Recommendation 2011/3 on furthering the protection and conservation of the Little shearwater
(Puffinus assimilis baroli)
OSPAR Recommendation 2011/4 on furthering the protection and conservation of the Balearic shearwater
(Puffinus mauretanicus)
OSPAR Recommendation 2011/5 on furthering the protection and conservation of the Black-legged kittiwake
(Rissa tridactyla tridactyla)
OSPAR Recommendation 2011/6 on furthering the protection and conservation of the Roseate tern (Sterna
dougallii)
OSPAR Recommendation 2011/7 on furthering the protection and conservation of the Thick-billed murre
(Uria lomvia)
International Maritime Organization (IMO) and the London Convention
No spatially based measures have been introduced by IMO or the London Convention for Areas Beyond National
Jurisdiction in the Northeast Atlantic. Many general IMO measures (e.g. ballast water exchange protocols, disposal of
waste) will apply to these areas.
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ICES Advice 2013, Book 1
International Seabed Authority (ISA)
According to UNCLOS ISA is the competent authority that regulates mining and mineral extraction in “The Area”
(http://www.isa.org.jm/en/scientific/exploration). A memorandum of understanding was signed between the OSPAR
Convention and the International Seabed Authority in June 2011 to facilitate consultation and sharing of data and
information of relevance, with a view to promoting and enhancing a better understanding and coordination of their
respective activities.
There are three types of deep-sea mineral resources that are of commercial interest: polymetallic nodules, polymetallic
sulphides, and cobalt-rich ferromanganese crusts. So far, ISA has only adopted the regulatory framework for the
exploration of deep-sea mineral resources, including very strict regulations to ensure full environmental impact
assessments are undertaken prior to any activity in “The Area”. The framework for the exploitation of these resources has
yet to be developed and adopted.
There are several areas in the Northeast Atlantic identified as having deposits of mineral resources of possible commercial
interest, but exploratory mining cannot commence without adoption of a management framework.
Arctic Council
In follow-up to a recommendation to identify areas of heightened ecological and cultural significance, a report is being
prepared for the Arctic Council’s Protection of the Arctic Marine Environment Working Group (PAME). If the areas are
agreed, it is recommended that Arctic states, where appropriate, should encourage implementation of measures to protect
these areas from the impacts of Arctic marine shipping, in coordination with all stakeholders and consistent with
international law.
National and European Union
At the national and EU levels, many relevant measures for the protection of areas have not been systematically reviewed
by ICES. Several of these measures implement more general international obligations, for instance under the Convention
on Trade in Endangered Species.
Sources
ICES. 2013a. Vulnerable deep-water habitats in the NEAFC Regulatory Area. In Report of the ICES Advisory
Committee, 2013, Section 1.5.5.1. ICES Advice, 2013, Book 1.
ICES. 2013b. Report of the Workshop to Review and Advise on EBSA Proposed Areas (WKEBSA), 27–31 May 2013,
Copenhagen, Denmark. In draft.
ICES Advice 2013, Book 1
143
1.5.5.7
Special Request, Advice September 2013
ECOREGION
General advice
SUBJECT
OSPAR/NEAFC special request on review and reformulation of four
EBSA Proformas
Advice summary
ICES provided advice to OSPAR and NEAFC in June 2013 (OSPAR/NEAFC special request on review of the results of
the Joint OSPAR/NEAFC/CBD Workshop on Ecologically and Biologically Significant Areas (EBSAs) (ICES Advice
2013 section 1.5.5.5).
Following discussion with OSPAR and NEAFC, ICES (using experts of the review group) agreed to reformulate and
revise four of the EBSAs and provide new updated maps.
The material consists of scientifically updated Proformas for the following EBSAs:
•
•
•
•
Mid-Atlantic Ridge North of the Azores and South of Iceland
Charlie-Gibbs Fracture Zone (and the Sub-Polar Front)
The Hatton and Rockall Banks and the Hatton-Rockall Basin
The Arctic Ice habitat – multiyear ice, seasonal ice – marginal ice zone
During the update on the Charlie-Gibbs Fracture Zone (CGFZ) it appeared that the Sub-Polar Front, which was included
in the previous version of the Proforma, could not be scientifically supported with the evidence to hand at the time and
was therefore excluded from the CGFZ Proforma. A short note explains the reasons and consequences for the exclusion.
•
Note on the Sub Polar Front.
The five documents are scientifically updated technical documents and appended to this advice.
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ICES Advice 2013, Book 1
ANNEX 1
Draft Proforma: The Hatton and Rockall Banks and the Hatton-Rockall Basin
Presented by: The Joint OSPAR/NEAFC/CBD Scientific Workshop. Reviewed by an ICES expert group and
revised by Francis Neat and J. Murray Roberts.
Based on an original proposal submitted by: Dr David Billett and Dr Brian Bett (Deepseas Group, Ocean
Biogeochemistry and Ecosystems Department, NOC, UK), Prof. Philip Weaver (Seascape Consultants Ltd and National
Oceanography Centre, UK), Prof Callum Roberts and Ms Rachel Brown (Environment Department, University of York),
Dr Murray Roberts and Dr Lea-Anne Henry, (Centre for Marine Biodiversity and Biotechnology, School of Life
Sciences, Heriot-Watt University), Dr Kerry Howell and Dr Jason Hall-Spencer (Marine Biology and Ecology Research
Centre, Marine Institute, University of Plymouth); Dr Andrew Davies (School of Ocean Sciences, Bangor University);
Dr Bhavani Narayanaswamy (Scottish Association for Marine Science, Oban), Prof. Monty Priede (OceanLab, University
of Aberdeen); Dr David Bailey (Division of Environmental and Evolutionary Biology, University of Glasgow); Prof.
Alex Rogers (University of Oxford) and Mr Ben Lascelles (Global Seabird Programme, Bird Life International)
Abstract
The Hatton and Rockall Banks, associated slopes and connecting basin, represent offshore bathyal habitats between 200
to 1500 m that constitute a unique and prominent feature of the NE Atlantic. The area has high habitat heterogeneity and
supports a wide range of benthic and pelagic species and ecosystems. There is significant fishing activity in the area,
including bottom trawling, long-lining, and midwater fisheries.
Introduction
The Hatton and Rockall Banks are large isolated geomorphological features in the NE Atlantic. Formed from continental
crust, they span depths from c. 200 to 2000m. The banks are linked by the Hatton-Rockall Basin at a depth of
approximately 1300 m which has particular geomorphological features and habitats. The gently sloping banks and the
basin provide a contrasting geological setting to the tectonically active Mid-Atlantic Ridge to the west and the generally
steeper slopes of the European continental margin to East. The banks encompass a large depth range with strong
environmental gradients (e.g. temperature, pressure, and food availability) that give rise to a high diversity of species and
habitats (Billett, 1991; Bett, 2001; Howell et al., 2002; Davies et al. 2006; Roberts et al. 2008; Howell et al., 2009; Howell
et al. 2010). Environmental heterogeneity is positively correlated with biological diversity at a variety of scales (Menot
et al. 2010) as indicated by significantly elevated levels of species change across space (in areas such as Hatton Bank
(Roberts et al. 2008).
Changes in pressure and temperature have significant effects on the biochemistry of species, influencing cell membrane
structure and enzyme characteristics (Gage and Tyler, 1991). In general, each species is adapted to a particular range of
environmental conditions. Each may occur over a depth range of about 500 m, but the depths where any particular species
is abundant, and therefore able to form viable populations, is generally limited to a much more restricted depth range of
100 to 200 m (Billett, 1991; Howell et al., 2002). There is evidence that such depth-related effects promote speciation
(Howell et al., 2004). In addition, the progressive decrease in organic matter availability with increasing depth (with some
patchiness depending on geomorphology) leads to a reduction of carnivores and an increase in detritus feeders (Billett,
1991). Taken together such environmental changes lead to a continuous sequential change in species composition with
depth, and biological community characteristics that are radically different to those known in shelf seas.
The area is influenced by a number of different water masses and there is considerable interaction between the topography
and physical oceanographic processes, in some areas focusing internal wave and tidal energy (Ellett et al. 1986) which
results in strong currents and greater mixing. This may give rise to highly localized and specialised biological
communities such as sponge aggregations and coral gardens. The mixing of Arctic and Atlantic water in the North of the
area means that species from both ecosystems are represented causing enhanced species diversity.
The Rockall Bank supports shallow demersal fisheries targeting haddock, gurnard and monkfish (Neat & Campbell 2010).
The slopes and the Hatton Bank are target areas for deep-water bottom fisheries for Ling (Molva molva), Blue Ling
(Molva dypterygia), Tusk (Brosme brosme), Roundnose Grenadier (Coryphaenoides rupestris) and Black Scabbardfish
(Aphanopus carbo). In the past deepwater sharks were also caught in the area, but this is now prohibited. A wide variety
of other fish species are also taken as by-catch (Gordon et al., 2003; Large et al., 2003; ICES 2010). Some of the deepwater target species have characteristic low productivity and extended generation times. Deep-water fisheries have
ICES Advice 2013, Book 1
145
significant effects not only on target fish species, but also on the benthic fauna (Le Guilloux et al., 2009; Clark et al.
2010).
Major wide-ranging Northeast Atlantic epipelagic fish stocks, e.g. mackerel and blue whiting, use the Hatton-Rockall
area for parts of their life cycle and are targeted by international fisheries. The slopes of the banks and channels between
the banks have a diverse bathy- and mesopelagic fish community sustained by the zooplankton production in the
epipelagic zone. The pelagic communities are similar to, and probably extensions of, those in adjacent oceanic waters
along the European continental margin.
Some invertebrate species, such as cold-water corals and sponges, provide important structural habitat heterogeneity.
These habitats are highly susceptible to physical damage and may take hundreds, if not thousands, of years to reform
(Hall-Spencer et al. 2002; Roberts et al. 2009; Söffker et al., 2011).
Current fisheries control measures on Hatton and Rockall Bank have focused mainly on the protection of corals (HallSpencer et al., 2009) and sponges (ICES 2013).
There is no evidence currently that the seabed at depth greater than 1500 m in the area is significantly different from
comparable depths in the rest of the NE Atlantic. The majority of the features considered here occur at depths shallower
than 1500 m and this therefore forms an appropriate delimitation of the EBSA.
Location
The EBSA would comprise the seabed and pelagic zones shallower than 1500 m above the Rockall and Hatton Banks
and the adjoining Hatton-Rockall Basin. This extends into adjacent EEZs, but the current proposal refers to the ABNJ
only. The area beyond national jurisdiction lies wholly within regions under consideration by the Commission on the
Limits of the Continental Shelf.
Feature description
Benthic and pelagic communities to depths of 1500 m in and around the Hatton and Rockall Banks and Basin. Seabed
communities include cold-water coral formations and sponge aggregations. Geomorphologically complex seabed types
include rocky reefs, carbonate mounds, polygonal fault systems and sedimentary slopes, slides and fans. Pelagic
communities include those inhabiting bathy-, meso- and epi-pelagic zones, including zooplankton, fish, cetaceans, turtles
and seabirds.
1. Benthic and benthopelagic communities
Cold-water coral
Observations in the early 1970s found cold-water coral communities on the Rockall Bank down to a depth of 1,000 m
(Wilson, 1979a). Thickets of Lophelia pertusa occurred principally at depths between 150-400m 10. Large coral growth
features have recently (2011) been discoveredto be still present on the northern Rockall Bank (Huvenne et al., 2011,
Roberts et al. 2013). Bottom-contact fishing can result in significant adverse impacts to these habitats.
Frederiksen et al. (1992) reported a high diversity of corals on the northern Hatton Bank, including Paragorgia,
Paramuricea, Isididae and Antipatharia as well as the scleractinians L. pertusa and M. oculata. Since these observations
further records of coral frameworks have been noted throughout the Rockall, Hatton area, including the Logachev Mounds
and the Western Rockall Bank Mounds (Kenyon et al., 2003; Roberts et al., 2003; Narayanaswamy et al., 2006; Howell
et al., 2007; Durán Muñoz et al. 2009).
Recent surveys identified many areas that contained the cold-water coral L. pertusa throughout the Rockall and Hatton
Banks (Narayanaswamy et al., 2006; Howell et al., 2007; Roberts et al. 2008; Durán Muñoz et al. 2009). Several areas
on the Hatton Bank contained pinnacles and mounds with extensive biogenic structures including areas of coral rubble
around the flanks of the coral mounds. Coral frameworks are known from the Hatton Bank (Durán Muñoz et al. 2009),
and are predicted to occur over focused regions of the Hatton Bank (Howell et al., 2011). Geophysical evidence suggests
that these have formed by successive coral growth and sedimentation episodes, as in other regions (Roberts et al., 2006),
forming coral carbonate mounds (Roberts et al. 2008). Single and clustered coral carbonate mounds have also been
discovered on the southeast of Rockall Bank. These structures are comprised mostly of L. pertusa and can reach heights
of 380 m in water depths of between 600-1000 m (Kenyon et al., 2003; Mienis et al., 2006; Mienis et al., 2007).
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http://www.lophelia.org/lophelia/case_4.htm
ICES Advice 2013, Book 1
Cold-water coral frameworks have been reported to support over 1,300 species in the Northeast Atlantic, some of which
have yet to be described (Roberts et al., 2006). New species and associations have been reported recently (e.g. Myers &
Hall-Spencer 2007; Le Guilloux et al., 2010; Söffker et al. 2011). The corals may provide an important habitat for certain
fish species (Fosså et al., 2002; Söffker et al. 2011; Henry et al 2013), including commercial species Sebastes sp., Molva
molva, Brosme brosme, Anarhichas lupus and Pollachius virens (Mortensen et al., 1995; Freiwald, 2002; Hall-Spencer
et al., 2002). Pregnant Sebastes viviparus may use the reef as a refuge or as a nursery ground to raise their offspring
(Fosså et al., 2002) as recently observed on the northern Rockall Bank (Huvenne et al., 2011, Roberts et al. 2013). As
well as living reefs, dead coral framework and coral rubble provide a structural habitat. Jensen and Frederiksen (1992)
collected Lophelia and found 256 species; a further 42 species were identified amongst coral rubble.
There has been only limited research into linkages between coral and other deep-water ecosystems. Compared to the
south-eastern US and Gulf of Mexico, molecular research has shown that northeastern Atlantic populations of L. pertusa
are moderately differentiated (Morrison et al. 2011) and form distinct subpopulations, but also that Rockall Bank corals
show some genetic similarity to those occurring on the New England Seamounts indicating some degree of connectivity
(Morrison et al. 2011). Lophelia pertusa exhibits high levels of inbreeding through asexual reproduction at several sites
in the NE Atlantic, suggesting a high incidence of self-recruitment in local populations (Le Goff-Vitry and Rogers, 2005).
Further molecular studies are required in local areas to gauge the importance of the Rockall and Hatton Banks in the life
history of regional coral populations.
In summary the cold-water corals fit the following EBSA criteria:
Uniqueness or rarity
•
Large areas of cold-water corals and sponges have been reported in the area. Some of these have been destroyed
by demersal trawling, but in certain areas, e.g. SW Rockall Bank, extensive patches of coral framework still exist.
Special importance for life-history stages
•
Cold-water corals and areas of natural coral rubble provide highly diverse habitats
Importance for threatened, endangered or declining species/habitats
•
•
The cold-water corals and natural rubble contain very large numbers of invertebrate species including giant
protozoans on nearby sedimentary habitats (xenophyophores), vase shaped white sponges, actiniarians,
antipatharian corals, hydroids, bryozoans, asteroids, ophiuroids, echinoids, holothurians and crustaceans.
The distribution of cold-water coral has been severely reduced in the area over the last 30 years
Vulnerability, fragility, sensitivity, or slow recovery
•
•
There is a high diversity of corals, including bamboo coral (Isididae), black coral (Antipatharia) as well as the reef
forming stony corals (Scleractinia), though some of these may now be reduced in distribution occurring in patches.
Cold-water coral habitats are easily impacted and recover very slowly, if at all.
Biological diversity
•
Cold-water corals provide diverse habitats for other invertebrates and fish.
Sediment communities
The Hatton and Rockall Banks support many different habitats each with their own depth-related species assemblages
(Narayanaswamy et al., 2006; Howell et al., 2007; Roberts et al. 2008; Howell et al., 2009). Local seabed morphology
in this region is ultimately controlled by hydrography and oceanography (Due et al. 2006; Sayago-Gil et al. 2010), which
creates heterogeneity in sediment types including mud, exposed bedrock, fine sediments, living coral framework and
coral debris that – this habitat heterogeneity has a major influence on species diversity and turnover (Roberts et al. 2008).
A great variety of large invertebrate fauna (megafauna) occur in this region including giant protozoans (xenophyophores),
vase shaped white sponges, actiniarians, antipatharian corals, hydroids, bryozoans, asteroids, ophiuroids, echinoids,
holothurians and crustaceans (Narayanaswamy et al., 2006; Howell et al., 2007; Roberts et al. 2008). Large mega-infauna
such as echiuran worms are evident from observations of their feeding traces. Little is known, however, of the smaller
fauna living within the sediment. The Hatton-Rockall Basin is known to host a particular geomorphology known as a
polygonal fault system (Berndt et al 2012). The faults in the Hatton-Rockall Basin have surface expression, i.e. a network
of interlinked channels across the level seafloor. These fault structures were confirmed again in 2011 (Huvenne et al.,
2011). The flanks of the gullies appear to support extensive, dense aggregations of mixed species sponge communities.
ICES Advice 2013, Book 1
147
A key interest / conservation concern in such a geological setting would be the occurrence of cold-seep communities.
Large carbonate blocks were encountered that were likely formed as a result of seafloor fluid escape. In 2012 the first
evidence of an active cold-seep ecosystem in the area was suggested by the collection of chemosynthetic bivalves and
polychaete worms (ICES 2013) on the eastern margin of Hatton-Rockall Basin at a depth of 1200 m. The species are new
to science and suggest there is a lot still to learn of the seafloor and ecology of the Hatton and Rockall Banks.
The megafauna on the Hatton and Rockall Banks are largely species known from the wider NE Atlantic continental
margin (Gage et al. 1983; Gage et al., 1985; Mauchline et al., 1986; Harvey et al., 1988; Rice et al., 1991). These studies
focused on sedimented areas within the EEZs of the UK and Ireland and provide a lot of information on the life history
characteristics of the species including information on growth and reproduction. Apart from some species that produce
small eggs (indicative of planktotrophic development) in a seasonal cycle, most species conform to the life history
characteristics typical of the deep sea of larger egg size, lower fecundity and greater generation times (Gage and Tyler,
1991). This is an adaptation to the low food input to the deep sea, which leads to the rapid decrease in biomass with
increasing depth (Lampitt et al., 1986; Wei et al., 2010). Fauna adapt to lower food availability in the deep sea by a
number of trade-offs, one of which is a reduction in reproductive effort and longer generation times. The majority of
species, therefore, are highly susceptible to repeated physical disturbance.
In summary the sediment communities fit the following EBSA criteria:
Uniqueness or rarity
•
•
The area has considerable environmental heterogeneity, and therefore biological diversity, as a result of its large
depth range and strong environmental gradients. Habitat-forming sessile benthic communities, such as those of
giant protozoans and sponges, are common.
The area of polygonal faults may be a unique seabed feature and the presence of newly described chemosynthetic
bivalves and polychaete worms suggests the area may have unique communities.
Importance for threatened, endangered or declining species/habitats
•
The area comprises a patchwork of habitats with species changing consistently with both habitat type and
increasing to depths of 1500 m. Some habitats are threatened by direct impacts (e.g. trawling).
Vulnerability, fragility, sensitivity, or slow recovery
•
Many of the species have reproductive cycles with long generation times leading to very slow and episodic
recoveries following human impact. Most deep-sea species are particularly susceptible to degradation and depletion
by human activity.
Biological productivity
•
There are localised areas of concentrated production depending on geomorphology and hydrography, but little
evidence that the area has an enhanced productivity relative to other areas.
Biological diversity
•
Benthic and pelagic communities occupy all depths in and around the Hatton and Rockall Banks and Basin. Seabed
communities include cold-water corals and sponge aggregations. Seabed geomorphology is diverse with examples
of rocky reefs, carbonate mounds, polygonal fault systems, and steep and gentle sedimentary slopes. This high
habitat heterogeneity supports a high number of species and diverse communities.
Demersal fish
The deep-water fish of the NE Atlantic continental margin are generally well-known following comprehensive and
extensive surveys of the region (e.g. Gordon & Duncan, 1985; Merrett et al., 1991; Mauchline et al. 1986 and Rice et al.
1991). Species of commercial importance are reviewed by Gordon et al. (2003) and Large et al. (2003) and for fish
associated with cold-water corals by Söffker et al. (2011). Fish species diversity increases to depths of approx. 1500 m
on the continental slopes and declines thereafter (Campbell et al 2011). The shallow water fish assemblage on Rockall
can be described as an impoverished sub-set of that found in adjacent continental shelf areas, but one that has a
significantly different community composition (Neat & Campbell 2010). Recent surveys have found that the western
slope of the Rockall Bank has a slightly different fish assemblage than the adjacent European slope with several species
of a more southern affinity present (F. Neat unpublished data). Blue ling is known to spawn in a few locations on Rockall
bank and at Hatton bank (Large et al 2008).
148
ICES Advice 2013, Book 1
The detailed sampling in the Porcupine Seabight in the 1970s and 1980s took place before the start of deep-water
commercial fishing. More recent sampling of the same area in the 1990s and 2000s can be used to compare fish
communities before and after bottom trawling (Bailey et al. 2009). These data show that over 70 fish species have been
impacted by the fishing activity, of which only 4-5 are target commercial species. The area impacted is up to 2.5 times
larger than the area fished because the home range of many the fish extends into considerably deeper waters. In the past
decade, however, there is evidence that this initial steep decline in abundance has been halted, at least in one of the major
groups of fishes, the grenadiers (Neat & Burns 2010). At the northern limits of the area where Arctic water masses mix
with Atlantic water cold-water species such as Greenland Halibut and Roughhead Grenadier are present adding to the
diversity of species in the area.
In summary the demersal fish fit the following EBSA criteria:
Vulnerability, fragility, sensitivity, or slow recovery
•
Many of the deep demersal fish have very slow recovery times as a result of their slow reproductive rate compared
to pelagic fish.
2. Pelagic communities (plankton, nekton, birds)
Fish: Mackerel, blue whiting and other wide-ranging pelagic fish such as epipelagic sharks and tuna-like species use the
area during parts of their life-cycle, for feeding or as migration corridors. For blue whiting the slope area is used as a
spawning area. Mackerel eggs and larvae from spawning areas further south drift through the area.
Cetaceans: Phocoena phocoena have been observed over the shallower parts of Rockall Bank, but It is unlikely that the
area is of particular importance for the species. Limited numbers of the endangered Blue whale (Balaenoptera musculus)
and the critically endangered northern right whale (Eubalaena glacialis) have also been observed in this area (Cronin and
Mackey, 2002; Hammond et al., 2006).
Seabirds: Analyses of satellite tracking data hosted at www.seabirdtracking.org (Table 1) found the area to be used by
multiple species through the year. The site is used by Manx Shearwaters (Puffinus puffinus) during the breeding season
(Apr-Sept) from Iceland and UK colonies. From September until November tracked individuals of Cory’s Shearwater
(Calonectris diomedea) from 3 colonies, Sooty Shearwater (Puffinus griseus), Fea’s Petrel (Pterodroma feae) and Zino’s
Petrel (Pterodroma madeira) used the area. Studies of tracked Atlantic Puffin (Fratercula arctica) from Skomer and Isle
of May colonies found the site to be important during the overwintering phase (Aug-Apr) (Harris et al. 2010, Guilford et
al. 2011). In addition to tracking data, at-sea survey data confirms many more species within the area (e.g. Cronin and
Mackey, 2002).
Feature condition, and future outlook
Demersal fish have been targets of extensive fisheries for decades, expanding primarily in the latter half of the 1980s.
Although satisfactory stock assessments were seldom achieved, the probable declines in abundance and vulnerability of
many of the target species have been reflected in advice from ICES for many years (ICES 1996 onwards, Large et al.,
2003). A range of management actions by NEAFC and relevant coastal states have been implemented to reduce fishing
effort and facilitate recovery of target species and some associated by-catch species. A similar range of measures applies
to species inhabiting the shallowest areas, e.g. haddock.
Epipelagic species such as mackerel and blue whiting, and large pelagic sharks and tuna-like species occurring in the area
straddle between ABNJ and several EEZs and the fisheries are managed by relevant coastal states, NEAFC and ICCAT.
Cetaceans are managed by the IWC. The management is based on recurrent stock assessments by ICES and other advisory
bodies.
Records of the physical impact of deep-water trawling west of Scotland extend back to the late 1980s (Roberts et al.,
2000; Gage et al., 2005) and studies using VMS data show that fishing activity potentially affects much of the HattonRockall area (Hall-Spencer et al. 2009; Benn et al. 2010). Damage may occur to structural species such as corals and
sponges, which may take hundreds to thousands of years to recover (Hall-Spencer et al., 2002; Davies et al. 2007; Roberts
et al., 2009; Hogg et al. 2010).
A recent survey (2011) has documented extensive destruction of coral framework on the northern Rockall Bank (Huvenne
et al. 2011) in waters adjacent to the area currently being described. This expedition also encountered evidence of trawling
impact on the megafauna of open sedimented areas, with photographic surveys in the area of the 'Haddock Box' (Rockall
Bank) showing frequent occurrence of physically damaged holothurians - thought to be net escapees or discarded byICES Advice 2013, Book 1
149
catch. Cold seep communities are vulnerable to trawling impacts; they are typically highly localised and are of a relatively
small scale such that they could be eliminated by a single trawl. Cold seeps are OSPAR priority habitats for which there
are considerable concerns regarding the effects of bottom trawling (van Dover et al. 2011a, b).
Some of the benthic communities of the Hatton and Rockall Banks have already been significantly affected by deep-water
fishing (ICES WGDEC, 2007). The effects on deep-water fish may extend to waters deeper than those utilised by trawl
fisheries (Bailey et al., 2009). Broad-scale multibeam surveys have revealed a diverse range of geomophological features
and sediment types on Hatton Bank (Jacobs and Howell, 2007; Stewart and Davies, 2007; MacLachlan et al., 2008;
Sayago-Gil et al., 2010). These physical environment maps, coupled with targeted biological surveys have resulted in the
production of biological habitat maps for the region (Howell et al., 2011) which highlight the range and diversity of noncoral seabed features present in the area.
Assessment against CBD EBSA Criteria
Table 1.
Relation of each of the CBD criteria to the proposed area relating to the best available science. Note that a
candidate EBSA may qualify on the basis of one or more of the criteria, the boundaries of the EBSA need
not be defined with exact precision.
CBD EBSA
Criterion
Description
The area contains either (i) unique (“the only one of its
kind”), rare (occurs only in few locations) or endemic
species, populations or communities, and/or (ii) unique,
rare or distinct, habitats or ecosystems; and/or (iii) unique
or unusual geomorphological or oceanographic features
Explanation for ranking
Uniqueness or
rarity
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
Know
High
X
•
The area has considerable environmental heterogeneity, and therefore biological diversity, as a result of its large depth
range and strong environmental gradients. Habitat-forming sessile benthic communities, such as those of giant protozoans
and sponges, are common.
•
Large areas of cold-water corals and sponges have been reported in the area. Some of these have been destroyed by
demersal trawling, but some areas of large coral frameworks still exist.
•
An area of polygonal faults may be a unique seabed feature and the recent discovery of cold-seep species that are new to
science suggests the area is very likely to be unique.
Areas that are required for a population to survive and
Special
X
thrive
importance for
life-history
stages of species
Explanation for ranking
•
•
Cold-water corals and areas of natural coral rubble provide highly diverse habitats
Parts of the Hatton-Rockall area are important as spawning areas for blue whiting, and the area is used as a corridor for a
range of migrating species including turtles.
Area containing habitat for the survival and recovery of
Importance for
X
endangered, threatened, declining species or area with
threatened,
significant assemblages of such species
endangered or
declining species
and/or habitats
Explanation for ranking
•
•
•
150
The cold-water corals and natural rubble contain very large numbers of invertebrate species including giant protozoans
(xenophyophores), vase shaped white sponges, actiniarians, antipatharian corals, hydroids, bryozoans, asteroids,
ophiuroids, echinoids, holothurians and crustaceans.
The distribution of cold-water coral has been severely reduced in the area over the last 30 years
The area comprises a patchwork of habitats with species changing consistently with both habitat type and increasing depth.
Some habitats are threatened by direct impacts (e.g. trawling), others may suffer indirectly e.g. through the creation of
sediment plumes by impacts of fishing gear in sensitive areas.
ICES Advice 2013, Book 1
Areas that contain a relatively high proportion of sensitive
Vulnerability,
habitats, biotopes or species that are functionally fragile
fragility,
(highly susceptible to degradation or depletion by human
sensitivity, or
activity or by natural events) or with slow recovery
slow recovery
Explanation for ranking
•
•
•
•
X
There is a high diversity of corals, including bamboo coral (Isididae), black coral (Antipatharia) as well as the reef forming
stony corals (Scleractinia), though some of these may now be reduced in distribution occurring in patches.
Cold-water coral habitats are easily impacted and recover very slowly, if at all
Many of the species have reproductive cycles with long generation times leading to very slow and episodic recoveries
following human impact. Most deep-sea species are particularly susceptible to degradation and depletion by human
activity and natural events.
Many of the demersal fish have very slow recovery times as a result of their slow reproductive rate compared to pelagic
fish. Stocks have already been diminished in some areas.
Area containing species, populations or communities with
Biological
comparatively higher natural biological productivity
productivity
Explanation for ranking
X
• While pelagic organisms may be more concentrated over the banks in the area, there is little evidence to suggest overall
enhanced productivity of the area.
Area contains comparatively higher diversity of
Biological
X
ecosystems, habitats, communities, or species, or has
diversity
higher genetic diversity
Explanation for ranking
•
•
•
Benthic and pelagic communities occupy all depths in and around the Hatton and Rockall Banks and Basin. Seabed
communities include cold-water corals, rocky reefs, carbonate mounds, polygonal fault systems, sponge aggregations,
steep and gentle sedimented slopes.
The Hatton and Rockall Banks and the Hatton-Rockall Basin have a high habitat heterogeneity that supports diverse
seabed communities.
Cold-water corals provide diverse habitats for other invertebrates and fish.
References
Bailey, D.M., Collins, M.A., Gordon, J.D.M., Zuur, A.F. & Priede, I.G. (2009) Long-term changes in deep-water fish
populations in the northeast Atlantic: a deeper reaching effect of fisheries? Proc. Roy. Soc. Lond. B. 276, 19651969
Benn, A.R., Weaver, P.P.E, Billett, D.S.M., van den Hove, S., Murdock, A.P., Doneghan, G.B. & Le Bas, T. (2010).
Human Activities on the Deep Seafloor in the North East Atlantic: An Assessment of Spatial Extent. PLoS One
5(9): e12730. doi:10.1371/journal.pone.0012730.
Berndt, C, Jacobs, C. L., Evans, A. J., Gay, A., Elliot, G., Long, D. and Hitchen, K. (2012) Kilometre-scale polygonal
seabed depressions in the Hatton Basin, NE Atlantic Ocean: Constraints on the origin of polygonal faulting
Marine Geology, 332/334 . pp. 126-133. DOI 10.1016/j.margeo.2012.09.013.
Bett, B.J. (2001) UK Atlantic Margin Environmental Survey: introduction and overview of bathyal benthic ecology. Cont.
Shelf Res. 21, 917-956.
Billett, D.S.M. (1991) Deep-sea holothurians. Oceanogr. mar. Biol. Ann. Rev. 29, 259-317.
Campbell, N. et al. 2010. Taxonomic indicators of deep water demersal fish community diversity on the Northeast
Atlantic continental slope. ICES J. Mar. Sci. 68, 365-378.
Clark M.R., Rowden A.A., Schlacher T., Williams A., Consalvey M., Stocks K.I., Rogers A.D., O'Hara T.D., White M.,
Shank T.M. & Hall-Spencer J.M. (2010) The ecology of seamounts: structure, function and human impacts.
Annu. Rev. Mar. Sci. 2, 253-278.
Costello, M.J., McCrea, M., Freiwald, A., Lundälv, T., Jonsson, L., Bett, B.J., Van Weering, T.C.E., De Haas, H., Roberts,
J.M. & Allen, D. (2005) Role of cold-water Lophelia pertusa reefs as fish habitat in the NE Atlantic. In: Freiwald,
A., Roberts, J.M. (Eds.), Cold-water Corals and Ecosystems. Springer-Verlag, Berlin Heidelberg, pp. 771-805.
Cronin, M., Mackey, M. (2002) Cetaceans and Seabirds of the Hatton-Rockall Region, Cruise Report of the Geological
Survey of Ireland May 2002.
Davies, A.J., Narayanaswamy, B.E., Hughes, D.J. & Roberts, J.M. (2006) An introduction of the benthic ecology of the
Rockall-Hatton Area (SEA 7). Scottish Association for Marine Science, Oban, p. 94.
http://www.offshoresea.org.uk/
Davies, A.J., Wisshak, M., Orr, J.C. & Roberts, J.M. (2008) Predicting suitable habitat for the cold-water coral Lophelia
pertusa (Scleractinia). Deep-Sea Res. I 55, 1048-1062.
Davies. A., Roberts. J.M. & Hall-Spencer, J.M. (2007) Preserving deep-sea natural heritage: emerging issues in offshore
conservation and management. Biol. Cons. 138, 299-312.
ICES Advice 2013, Book 1
151
Due, L., van Aken. H.M., Boldreel. L.O. & Kuijpers, A. (2006) Seismic and oceanographic evidence of present-day
bottom-water dynamics in the Lousy Bank–Hatton Bank area, NE Atlantic. Deep-Sea Research I53:1729-1741
Durán Muñoz, P., Sayago-Gil, M., Cristobo, J., Parra, S., Serrano, A., Díaz del Rio, V., Patrocinio, T., Sacau, M., Murillo,
F.J., Palomino, D. & Fernández-Salas, L.M. (2009) Seabed mapping for selecting cold-water coral protection
areas on Hatton Bank, Northeast Atlantic. ICES J. Mar. Sci. 66, 2013-2025
Ellett, D.J., Edwards, A. & Bowers, R. (1986) The hydrography of the Rockall Channel – an overview. Conference
Proceedings Symposium on the Oceanography of the Rockall Channel, Edinburgh (UK), 27-29 Mar 1985.
Fosså, J.H., Mortensen, P.B. & Furevik, D.M. (2002) The deep-water coral Lophelia pertusa in Norwegian waters:
distribution and fishery impacts. Hydrobiologia 471, 1-12.
Frederiksen, R., Jensen, A. & Westerberg, H. (1992) The distribution of the scleractinian coral Lophelia pertusa around
the Faeroe Islands and the relation to internal tidal mixing. Sarsia 77, 157-171.
Freiwald, A. (2002) Reef-forming cold-water corals. In: Wefer, G., Billett, D., Hebbeln, D., Jorgensen, B.B., Schluter,
M., Van Weering, T. (Eds.), Ocean Margin Systems. Springer-Verlag Berlin Heidelberg, Berlin, pp. 365-385.
Gage, J.D. & Tyler, P.A. (1991) Deep-Sea Biology. A Natural History of Organisms at the Deep-Sea Floor. Cambridge
University Press. 504pp.
Gage, J.D., Billett, D.S.M., Jensen, M. & Tyler, P.A. (1985) Echinoderms of the Rockall Trough and adjacent areas. 2.
Echinoidea and Holothurioidea. Bull. Br. Mus. Nat. Hist. (Zool.), 48, 173-213.
Gage, J.D., Pearson, M., Clark, A.M., Paterson, G.L.J. & Tyler, P.A. (1983) Echinoderms of the Rockall Trough and
adjacent areas. 1. Crinoidea, Asteroidea and Ophiuroidea. Bull. Br. Mus. nat. Hist. (Zool.) 45, 263-308.
Gage, J.D., Roberts, J.M., Hartley, J.P. & Humphery, J.D. (2005) Potential impacts of deepsea trawling on the benthic
ecosystem along the Northern European Continental Margin: A review. In: Barnes, P.W., Thomas, J.P. (Eds.),
Benthic Habitats and the Effects of Fishing. American Fisheries Society, Bethesda, Maryland, pp. 503-517.
Gordon, J. D. M., O. A. Bergstad, I. Figueiredo, and G. Menezes. 2003. Deep-water Fisheries of the Northeast Atlantic:
I. Description and Current Trends. J. Northw. Atl. Fish. Sci. 31: 137-150.
Gordon, J.D.M. & Duncan, J.A.R. (1985) The ecology of the deep-sea benthic and benthopelagic fish on the slopes of the
Rockall Trough, northeastern Atlantic. Prog. Oceanogr. 15, 37-69.
Guilford, T., Freeman, R., Boyle, D., Dean, B., Kirk, H., Phillips, R.A., Perrins, C. (2011) A dispersive migration in the
Atlantic Puffin and its Implications for Migratory Navigation, Plos One, 6(7), e21336.
Hall-Spencer J.M., Allain V. & Fossa J.H. (2002) Trawling damage to Northeast Atlantic ancient coral reefs. Proc. Roy.
Soc. Lond. B. 269, 507-511.
Hall-Spencer, J.M., Tasker, M., Söffker, M., Christiansen, S., Rogers, S., Campbell, M. & Hoydal, K. (2009) The design
of Marine Protected Areas on High Seas and territorial waters of Rockall. Mar. Ecol. Prog. Ser. 397, 305-308.
Harris, M.P., Daunt, F., Newell, M., Phillips, R.A., Wanless, S. (2010) Wintering areas of Atlantic Puffins Fratercula
arctica from a North Sea colony as revealed by geolocation technology, Mar Biol, 157, 827-836
Harvey, R., Gage, J.D., Billett, D.S.M., Clark, A.M. and Paterson, G.L.J. (1988) Echinoderms of the Rockall Trough and
adjacent areas. 3. Additional records. Bull. Br. Mus. (Nat. Hist.) (Zool.), 54 (4), 153-198.
Henry, L-A. & Roberts, J.M. (2007) Biodiversity and ecological composition of macrobenthos on cold-water coral
mounds and adjacent off-mound habitat in the bathyal Porcupine Seabight, NE Atlantic. Deep-Sea Res I 54,
654-672
Hogg, M.M., Tendal, O.S., Conway, K.W., Pomponi, S.A., van Soest, R.W.M., Gutt, J., Krautter, M. & Roberts, J.M.
(2010) Deep-sea Sponge Grounds: Reservoirs of Biodiversity. UNEP-WCMC Biodiversity Series No. 32.
UNEP-WCMC, Cambridge, UK
Howell, K., Billett, D.S.M. & Tyler, P.A. (2002). Depth-related distribution and abundance of seastars
(Echinodermata:Asteroidea) in the Porcupine Seabight and Porcupine Abyssal Plain, N.E. Atlantic. Deep-Sea
Res. I 49, 1901-1920.
Howell, K.L. (2010) A benthic classification system to aid in the implementation of marine protected area networks in
the deep / high seas of the NE Atlantic. Biol. Cons. 143, 1041–1056.
Howell, K.L., Davies J.S., Jacobs, C., and Narayanaswamy B.E. (2007). Broadscale Survey of the Habitats of Rockall
Bank, and mapping of Annex I ‘Reef’ Habitat. Joint Nature Conservation Committee Report. No. 422, 165p.
Howell, K.L., Davies J.S. & Narayanaswamy, B.E.(2010). Identifying deep-sea megafaunal epibenthic assemblages for
use in habitat mapping and marine protected area network design. J. Mar. Biol. Ass. UK 90, 33-68 .
Howell, K.L., Davies, J.S., Hughes, D.J. & Narayanaswamy, B.E. (2007) Strategic Environmental Assessment / Special
Area for Conservation Photographic Analysis Report. Department of Trade and Industry, Strategic
Environmental Assessment Report, UK, p. 163. Unpublished report.
Howell, K.L., Holt, R., Pulido Endrino, I. & Stewart, H. (2011) When the species is also a habitat: comparing the
predictively modelled distributions of Lophelia pertusa and the reef habitat it forms. Biol. Cons.
Howell, K.L., Mowles S. & Foggo, A. (2010) Mounting evidence: near-slope seamounts are faunally indistinct from an
adjacent bank. Mar. Ecol. 31, 52-62.
Howell, K.L., Rogers, A., Tyler, P.A. & Billett, D.S.M. (2004). Reproductive isolation among morphotypes of the
cosmopolitan species Zoroaster fulgens (Asteroidea:Echinodermata). Mar. Biol. 144, 977-984.
Husebø, A., Nottestad, L., Fosså, J.H., Furevik, D.M. & Jorgensen, S.B. (2002) Distribution and abundance of fish in
deep-sea coral habitats. Hydrobiologia 471, 91-99.
152
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Huvenne, V.A.I. et al. (2011) RRS James Cook Cruise 60, 09 May-12 Jun 2011. Benthic habitats and the impact of human
activities in Rockall Trough, on Rockall Bank and in Hatton Basin. (National Oceanography Centre Cruise
Report, No. 04) Southampton, UK: National Oceanography Centre, Southampton, 133pp.
ICES (2007) Report of the Working Group on Deep-Water Ecology (WGDEC), 26–28 February 2007, ICES Cm
2007/aCE:01 Ref lRC. International Council for the Exploration of the Sea, Copenhagen, Denmark, 57pp.
ICES 2010. Report of the Working group on the Biology and Assessemnt of Deepwater Fisheries Resources. www.ices.dk
Jacobs, C.L., Howell, K.L. (2007) Habitat investigations within the SEA4 and SEA7 area of the UK continental shelf.
MV Franklin Cruise 0206, 03-23 Aug 2006. Research and Consultancy Report No. 24. National Oceanography
Centre, Southampton. UK. 95pp.
Jensen, A. & Frederiksen, R. (1992) The fauna associated with the bank-forming deep-water coral Lophelia pertusa
(Scleractinaria) on the Faroe Shelf. Sarsia 77, 53-69.
Kenyon, N.H., Akhmetzhanov, A.M., Wheeler, A.J., van Weering, T.C.E., de Haas, H. & Ivanov, M.K. (2003) Giant
carbonate mud mounds in the southern Rockall Trough. Marine Geology 195, 5-30.
Lampitt, R.S., Billett, D.S.M. & Rice, A.L. (1986) The biomass of the invertebrate megabenthos from 500 to 4100m in
the North East Atlantic. Mar. Biol. 93, 69-81.
Large, P. A., C. Hammer, O. A. Bergstad, J. D. M. Gordon, and P. Lorance. 2003. Deep-water Fisheries of the Northeast
Atlantic: II. Assessment and Management Approaches. J. Northw. Atl. Fish. Sci. 31: 151-163.
Le Goff-Vitry & M.C. & Rogers, A.D. (2005) Molecular ecology of Lophelia pertusa in the NE Atlantic. In: Freiwald,
A., Roberts, J.M. (Eds.). Cold-water Corals and Ecosystems. Springer-Verlag, Berlin Heidelberg, pp. 653-662.
Le Guilloux, E., Hall-Spencer, J.M., Söffker, M.K. & Olu-Le Roy, K. (2010) Association between the squat lobster
Gastroptychus formosus (Filhol, 1884) and cold-water corals in the North Atlantic. J. Mar Biol. Ass. UK 90,
1363-1369.
MacLachlan SE, Elliot GM, Parson LM (2008) Investigations of the bottom current sculpted margin of Hatton bank, NE
Atlantic. Mar. Geol. 253:170–184
Mauchline, J., Ellett, D.J., Gage, J.D., Gordon, J.D.M. & Jones, E.J.W. (1986) A bibliography of the Rockall Trough.
Conference Proceedings Symposium on the Oceanography of the Rockall Channel, Edinburgh (UK), 27-29 Mar
1985.
Menot, L., Sibuet, M., Carney, R.S., Levin, L.A., Rowe, G.T., Billett, D.S.M., Poore, G., Kitazato, H., Vanreusel, A.,
Galéron, J., Lavrado, H.P., Sellanes, J., Ingole, B. & Krylova, E. (2010) New Perceptions of Continental Margin
Biodiversity. In: McIntyre, A., (Ed). Chapter 5. Life in the World’s Oceans: Diversity, Distribution and
Abundance. Wiley-Blackwell. 79-101.
Merrett, N.R., Gordon, J.D.M., Stehmann, M. & Haedrich, R.L. (1991) Deep demersal fish assemblage structure in the
Porcupine Seabight (eastern North Atlantic): slope sampling by three different trawls compared. J. Mar. Biol,
Ass. UK 71, 329-358.
Mienis, F., de Stigter, H.C., de Haas, H. & van Weering, T.C.E. (2009) Near-bed particle deposition and resuspension in
a cold-water coral mound area at the Southwest Rockall Trough margin, NE Atlantic. Deep-Sea Res. I 56, 10261038.
Morrison, C., Ross, S., Nizinski, M., Brooke, S., Järnegren, J., Waller, R., Johnson, R. & King, T. (2011) Genetic
discontinuity among regional populations of Lophelia pertusa in the North Atlantic Ocean. Cons. Genetics 12,
713-729
Mortensen, P.B., Hovland, M., Brattegard, T. & Farestveit, R. (1995) Deep-water bioherms of the scleractinian coral
Lophelia pertusa (L) at 64 degrees N on the Norwegian Shelf – Structure and associated megafauna. Sarsia 80,
145-158.
Myers, A.A. & Hall-Spencer, J.M. (2004) A new species of amphipod crustacean, Pleusymtes comitari sp. nov.,
associated with Acanthogorgia sp. gorgonians on deep-water coral reefs off Ireland. J. Mar. Biol. Ass. UK 84,
1029-1032.
Narayanaswamy, B.E., Howell, K.L., Hughes, D.J., Davies, J.S., Roberts, J.M. & Black, K.D. (2006) Strategic
Environmental Assessment Area 7 Photographic Analysis Report. 13. Department of Trade and Industry,
Strategic Environmental Assessment Report, UK, p. 179. Unpublished report.
Neat, F.C. & Burns, F. 2010. Stable abundance, but changing size structure in grenadier fishes (Macrouridae) over a
decade (1998-2008) in which deepwater fisheries became regulated. Deep Sea Res. I. 57, 434-440.
Neat, F. & Campbell, N. 2010. Demersal fish diversity of the isolated Rockall plateau compared with the adjacent west
coast shelf of Scotland. Biol. J. Linn. Soc. Lond. 104, 138-147.
Penny, A.J., Parker, S.J. & Brown, J.H. (2009) Protection measures implemented by New Zealand for vulnerable marine
ecosystems in the South Pacific Ocean. Mar Ecol. Prog. Ser. 397, 341-354.
Pollock, C & Barton, C. 2006. Offshore seabirds in the SEA 7 area. A report to the UK Department of Trade and Industry.
Rice, A.L., Billett, D.S.M., Thurston, M.H. and Lampitt, R.S. (1991). The Institute of Oceanographic Sciences Biology
Programme in the Porcupine Seabight: background and general introduction. J. Mar. Biol. Ass. U.K., 71, 281310.
Roberts, J.M., Harvey, S.M., Lamont, P.A., Gage, J.D. & Humphery, J.D. (2000) Seabed photography, environmental
assessment and evidence for deep-water trawling on the continental margin west of the Hebrides. Hydrobiologia
441: 173-183
ICES Advice 2013, Book 1
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Roberts, J.M. and shipboard party (2013) Changing Oceans Expedition 2012. RRS James Cook cruise 073 Cruise Report.
Heriot-Watt University. 224 pp.
Roberts, J.M., Henry, L-A., Long, D. & Hartley, J.P. (2008) Cold-water coral reef frameworks, megafaunal communities
and evidence for coral carbonate mounds on the Hatton Bank, north east Atlantic. Facies 54: 297-316
Roberts, J.M., Long, D., Wilson, J.B., Mortensen, P.B. & Gage, J.D. (2003) The cold-water coral Lophelia pertusa
(Scleractinia) and enigmatic seabed mounds along the north-east Atlantic margin: are they related? Mar. Poll.
Bull. 46, 7-20.
Roberts, J.M., Wheeler, A., Freiwald, A. & Cairns, S.D. (2009) Cold-water corals: The biology and geology of deep-sea
coral habitats. Cambridge University Press. 334pp.
Roberts, J.M., Wheeler, A.J. & Freiwald, A. (2006) Reefs of the deep: The biology and geology of cold-water coral
ecosystems. Science 213, 543-547.
Rogers, A.D. & Gianni, M. (2010) The implementation of the UNGA Resolutions 61/105 and 64/72 in the management
of deep-sea fisheries on the High Seas. Report of the Deep-Sea Conservation Coalition. International Programme
on the State of the Ocean, London, UK. 97pp.
Sayago-Gil M, Long D, Hitchen K, Díaz-del-Río V, Fernández-Salas LM, Durán-Muñoz P (2010) Evidence for currentcontrolled morphology along the western slope of Hatton Bank (Rockall Plateau, NE Atlantic Ocean). Geo-Mar.
Lett. 30, 99-111
Söffker, M., Sloman, K.A. & Hall-Spencer, J.M. (2011) In situ observations of fish associated with coral reefs off Ireland.
Deep-Sea Res. I 58, 818-825
Stewart, H A, and Davies, J S. 2007. Habitat investigations within the SEA7 and SEA4 areas of the UK continental shelf
(Hatton Bank, Rosemary Bank, Wyville Thomson Ridge and Faroe–Shetland Channel). British Geological
Survey Commercial Report, CR/07/051.
Tittensor, D.P., Baco-Taylor, A.R., Brewin, P., Clark, M.R., Consalvey, M., Hall-Spencer, J.M., Rowden, A.A.,
Schlacher, T., Stocks, K. & Rogers, A.D. (2009) Predicting global habitat suitability for stony corals on
seamounts. J. Biogeog. 36, 1111-1128
Van Dover, C., Smith CR, Ardron J, Dunn D, Gjerde K, Levin L, Smith S and the Dinard Workshop Contributors (2011a).
Uncharted waters: Placing deep-sea chemosynthetic ecosystems in reserve. Marine Policy 36, 378-381.
Van Dover, C., Smith CR, Ardron J, Dunn D, Gjerde K, Levin L, Smith S and the Dinard Workshop Contributors (2011b).
Environmental management of deep-sea chemosynthetic ecosystems: justification of and considerations for a
spatially-based approach. International Seabed Authority Technical Study 9. 29pp.
Vanreusel, A., Fonseca, G., Danovaro, R., et al. (2010) The contribution of deep-sea macrohabitat heterogeneity to global
nematode diversity. Mar. Ecol. 31, 66-77.
Wei, C-L. et al. (2010). Global Patterns and Predictions of Seafloor Biomass Using Random Forests. PLoS One 5 (12)
http://dx.plos.org/10.1371/journal.pone.0015323.
Wilson, J.B., (1979a) The distribution of the coral Lophelia pertusa (L.) [L. prolifera (Pallas)] in the North-East Atlantic.
J. Mar. Biol. Ass. UK 59, 149-164.
Wilson, J.B., (1979b) ‘Patch’ development of the deep-water coral Lophelia pertusa (L.) on Rockall Bank. J. Mar. Biol.
Ass. UK 59, 165-177.
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Maps and Figures
Figure 1
Map of the ABNJ area in the NE Atlantic with boundary of the Hatton-Rockall EBSA outlined in red. This
boundary approximates the 1500 m contour.
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Table 2
Contributors of data for the analysis of seabird satellite tracking are as follows; full details about each
dataset are available via www.seabirdtracking.org
Species
Site
Owner
Corys Shearwater
Azores
J. González-Solís
Corys Shearwater
Balearics
J. González-Solís
Corys Shearwater
Canaries
J. González-Solís
Corys Shearwater
Chafarinas
J. González-Solís
Corys Shearwater
Berlengas
P. Catry, J.P. Granadeiro
Corys Shearwater
Selvagens
M.A. Dias, P. Catry
Corys Shearwater
Selvagens
M.A. Dias, J.P. Granadeiro
Corys Shearwater
Veneguera
J. González-Solís
Sooty Shearwater
Bay Fundy
R. Ronconi
Sooty Shearwater
Falklands
A. Hedd
Sooty Shearwater
Gough
A. Hedd
Great Shearwater
Bay Fundy
R. Ronconi
Great Shearwater
Inaccessible Island
R. Ronconi, P. Ryan, M. Caroline Martin
Manx Shearwater
Iceland
I.A. Sigurðsson, Y. Kolbeinsson, J. González-Solís
Manx Shearwater
UK
A. Ramsay, J. González-Solís
Fea’s Petrel
Bugio
I. Ramirez, V. Paiva
Black-legged Kittiwake
Norway
T. Boulinier, D. Gremillet, J. González-Solís
Little Shearwater
Azores
V. Neves, J. González-Solís
Zino’s Petrel
Madeira
F. Zino, R.A. Phillips, M. Biscoito
Figure 2
156
Species occurrence by month within the Hatton-Rockall area, showing percentage of tracked population
for each species (and where relevant subpopulation) found within the area each month.
ICES Advice 2013, Book 1
Rights and permissions – Any requests to use the seabird tracking data shown for this site in any publication need to be
agreed with the data owners. An initial request should be sent to BirdLife International to coordinate this process. See
http://www.seabirdtracking.org/terms.php for full terms of reference
ICES Advice 2013, Book 1
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ANNEX 2
Draft Proforma: Mid-Atlantic Ridge North of the Azores and South of Iceland
Presented by: Based on the Joint OSPAR/NEAFC/CBD Scientific Workshop. Reviewed and revised by an ICES expert
group.
Abstract
The Mid-Atlantic Ridge (MAR) is the major topographic feature of the Atlantic Ocean. Within the OSPAR/NEAFC area
the Northern MAR separates the Newfoundland and Labrador Basins from the West-European Basin and the Irminger
from the Iceland Basin. The ridge crest is generally cut by a deep rift valley along its length, bordered by high rift
mountains, which are bordered by high fractured plateaus. This region is largely composed of volcanic rock and is the
foundation of the proposed EBSA. Hydrothermal venting occurs along the ridges and small-scale physiographic features,
including many small volcanoes (seamounts) and canyons, form near the ridge axis. The Moytirra vent field, within this
EBSA, is the only high temperature hydrothermal vent known between the Azores and Iceland. Endemic vent fauna are
associated with thermally active areas. The 2,500 m depth contour is used to inform the EBSA boundary.
Introduction
Mid-ocean ridge systems occupy a third of the ocean floor and are the site of the formation of new Earth’s crust (Heezen
1969). The Mid-Atlantic Ridge (MAR), a tectonic continental plate boundary, is the major topographic feature of the
Atlantic Ocean, extending over 12,000 km from Iceland to the Bouvet Triple Junction in the South Atlantic (Figure 1). It
divides the ocean longitudinally into two halves, each cut by secondary transverse ridges and interrupted by strike-slip
transform faults that offset the ridge in opposing directions on either side of the axis of seafloor spreading (e.g., the Charlie
Gibbs Fracture at 53ºN). Compared with other mid-ocean ridges, the MAR is a slow-spreading ridge where new oceanic
floor is formed with an average spreading rate of 2.5 cm per year (Malinverno 1990). Hydrothermal venting occurs along
the ridges and small-scale physiographic features, including many small volcanoes (seamounts) and canyons, form near
the ridge axis; the crest consists mostly of hard volcanic rock. The MAR is an area which captures the Earth’s geological
history, with outstanding representation of the major stages of Earth’s history, including the record of life, significant ongoing geological processes in the development of landforms and significant geomorphic or physiographic features.
The general physiography of the MAR was documented some time ago (Heezen el al. 1959). The ridge crest is generally
notched by a deep rift valley along its length, bordered by high rift mountains, which in turn are bordered by high fractured
plateaus (Heezen et al. 1959). These crest zones are generally well defined and present along the full length of the MAR
(Malinverno 1990). At approximately 50 -75 km from the axis of the ridge, the crest merges with sediment covered flanks
which extend down to the abyssal plain (van Andel and Bowin 1968). The flanks are composed of a succession of smooth
shelves, each from 2 to 100 km from the central axis and subdivided into upper, middle, and lower steps (Heezen el al.
1959) extending in some areas to depths of 4,572 m (Tolstoy and Ewing 1949). The flanks are generally covered with
soft sediments. However, van Andel and Bowin (1968) describe considerable variability in sediment depth in the southern
MAR, where the foothill region west of the ridge and the ridge slope are only thinly covered, while sedimentation in some
valleys can range from nothing to a thickness of several hundred meters. The depth of the ridge crest is highly variable
along its length. Malinverno (1990) conducted 46 profiles across the ridge axis from 0° to 50°N, with most of those
conducted south of the Azores between 10° and 35°N. The average depth of the axial crest in those profiles was
approximately 2,300 m but Malinverno demonstrated that depth was correlated with distance from the Azores and fracture
zone characteristics.
The MAR is divided into the Northern and Southern ridges near the equator by the deep Romanche Trench. Within the
OSPAR area the Northern MAR separates the Newfoundland and Labrador Basins from the West-European Basin and
the Irminger from the Iceland Basin. It has a profound role in the circulation of the water masses in the North Atlantic
(Rossby 1999, Bower et al. 2002, Søiland et al. 2008) with currents crossing the MAR over deep gaps in the ridge and
influencing upper-ocean circulation patterns (Bower et al. 2002). Canyons cut into the flanks may influence upward fluxes
of water and abyssal mixing (Speer and Thurnherr 2005).
Studies of volcanic rocks from the submerged MAR suggest that it consists largely of tholeiitic basalt with low values of
K, Ti, and P. In contrast, the volcanic islands which form the elevated caps on the Ridge are built of alkali basalt with
high values of Ti, Fe3+, P, Na, and K (Engel and Engel 1964). Variations in mineral content result from chemical and
isotopic heterogeneity in the mantle (White and Schilling 1978).
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Moytirra Vent Field
The Moytirra vent field is the only fully described high temperature hydrothermal vent known between the Azores and
Iceland, making it a unique geophysical structure in the high seas of the North Atlantic and within the MAR. It is situated
at 45°N on the 300 m high fault scarp of the eastern axial wall of the MAR, 3.5 km from the axial volcanic ridge crest
(Wheeler et al. 2013). It is basalt-hosted and its position suggests that it is heated by an off-axis magma chamber. This
type of base rock causes precipitation of iron and sulphide-rich minerals during mixing of the hot hydothermal vent fluids
(200-400°C) with cold, oxygenated sea water- hence the term “black smoker” (Figure 2). The Moytirra vent field consists
of three active vent sites emitting “black smoke" and producing a complex of chimneys and beehive diffusers. The largest
chimney is 18 m tall and very actively venting.
There may also be further unconfirmed vent sites on the MAR at 43 N, at 45 N and on the Reykjanes Ridge. In these
areas, plumes and/or anomalously high concentrations of Mn in the water column have been detected
http://www.interridge.org/irvents/
Location
The Mid-Atlantic Ridge (MAR) extends over 12,000 km from Iceland to the Bouvet Triple Junction in the South Atlantic
(Figure 1) and falls within the national jurisdictions of Iceland and the Azores. The proposed EBSA Mid-Atlantic Ridge
North of the Azores and South of Iceland is for a portion of the MAR within the high-seas areas of OSPAR and NEAFC
(Figure 3). Although the crest has an average depth of approximately 2,300 m (Malinverno 1990) it is variable, and the
2,500 m depth contour was used to inform the boundaries of the proposed EBSA as this captures the majority of the ridge
crest, and known distribution of deep-water corals (maximum 2,400 m) (Figure 3, Table 1). Within the proposed EBSA
the smaller physiographic feature, the Moytirra Vent Field, is located at latitude 45.833 and longitude -27.85 (Table 1).
Feature description
The Mid-Atlantic Ridge North of the Azores and South of Iceland is a unique geomorphological feature to the North
Atlantic Ocean and to the high-seas areas of NEAFC and OSPAR. Within this feature is a smaller unique feature, the
Moytirra vent field. The Moytirra vent field is the only high temperature hydrothermal vent known between the Azores
and Iceland, making it a unique geophysical structure in the high seas of the North Atlantic and within the MAR.
The fauna of the Northern MAR have not been fully described and it is premature to speculate on whether any species
are endemic, excepting vent-endemic organisms associated with the hydrothermal vents. Some new species have been
described and these may prove to be endemic to the proposed EBSA with further sampling.
The benthic fauna associated with the Northern MAR are known from detailed observations at a few locations. Priede et
al. (2013) used a variety of sampling gears to survey habitat, biomass and biodiversity in a segment of the Northern MAR
as part of a multinational and multidisciplinary project (MAR-ECO). They found that primary production and export flux
over the MAR were not enhanced compared with a nearby reference station over the Porcupine Abyssal Plain and biomass
of benthic macrofauna and megafauna were similar to global averages at the same depths. Also as part of MAR-ECO,
Mortensen et al. (2008) used an ROV to conduct video surveys along the MAR at 8 sites between the Reykjanes Ridge
and the Azores. Deep-water corals were observed at all locations at depths less than 1400 m (range 800-2400 m) and 40
coral taxa were observed, including observations of patches of Lophelia pertusa. Crinoids, sponges, the bivalve Acesta
excavata, and squat lobsters were associated with the Lophelia. None of those corals were recognized as new species to
science and all likely have broader distributions extending along the continental slopes and seamounts at similar latitudes
in the North Atlantic. Inevitably, 11 new species have been described arising from the MAR-ECO work and more are
likely to be discovered as the samples are fully processed. These include a new genus and species of foram (Incola
arantius gen. et sp. nov.), two new species of glass sponges of the genus Sympagella (Rossellidae), mushroom corals
(Anthomastus gyratus sp. nov. and Heteropolypus sol sp. nov.), a deep-sea scavenging amphipod (Hirondellea
namarensis sp. nov.), two new starfish (species of Hymenaster) and three species of elasipodid holothurians (Gebruk et
al. 2013).
MAR-ECO midwater and bottom trawls collected 54 species of cephalopods in 29 families (Vecchione et al. 2010). The
squid Gonatus steenstrupi was the most abundant cephalopod in the samples, followed by the squids Mastigoteuthis
agassizii and Teuthowenia megalops. A multispecies aggregation of large cirrate octopods dominated the demersal
cephalopods.
The demersal fish fauna of the MAR form two distinct groups with a faunal divide between 48 and 52°N (Hareide and
Garnes 2001) and species-specific differences with depth (King et al. 2006, Bergstad et al. 2008). Hareide and Garnes
(2001), using one trawl and three longline surveys, identified 56 species from 27 families of fish from between 400 and
2000 m depth along the MAR. In the northern part of the Ridge (north of 52°N) relatively common sub-Arctic species
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such as Sebastes spp., tusk (Brosme brosme) and Greenland halibut (Reinhardtius hippoglossoides) were dominant while
sub-tropical species such as golden eye perch (Beryx splendens) and cardinal fish (Epigonus telescopus) were dominant
species below 48°N. During the 2004 MAR-ECO expedition to the MAR, 8518 fish, representing 40 species and 17
families were caught with longlines (Fossen et al. 2008). The 59 longline sets were distributed across the ridge axis at
depths ranging from 400 to 4300 m at two locations: just north of the Azores archipelago and in the Charlie–Gibbs
Fracture Zone. Chondrichthyans (primarily Etmopterus princeps) dominated the catches and contributed nearly 60% to
both total biomass and abundance. King et al. (2006) recorded the scavenging fishes of the MAR using a baited
autonomous lander equipped with a time-lapse camera between 924 and 3420 m water depth along 3 east–west transects
at 42, 51 and 53°N across the MAR. They photographed 22 taxa with Synaphobranchus kaupii, Antimora rostrata and
Coryphaenoides (Nematonurus) armatus dominant. Abyssal species in the axial valley region were C. armatus,
Histiobranchus bathybius and Spectrunculus sp. No endemic demersal species have been reported although the zoarcid
eelpout Pachycara thermophilum, is a vent-endemic species associated with hydrothermal vents of the MAR
(Geistdoerfer 1994).
Sutton et al. (2008) examined the assemblage structure and vertical distribution of deep-pelagic fishes relative to MAR
with acoustic and discrete-depth trawling surveys in association with MAR-ECO. A 36-station, zig-zag survey along the
Mid-Atlantic Ridge from Iceland to the Azores covered the full depth range (0 to >3000 m), from the surface to near the
bottom, using a combination of gear types to sample the pelagic fauna. Dominant families of pelagic fish included
Gonostomatidae, Melamphaidae, Microstomatidae, Myctophidae, and Sternoptychidae and 99 species of pelagic fish
were found concentrated particularly north of the Charlie-Gibbs Fracture Zone. Sutton et al. (2008) found that abundance
per volume of deep-pelagic fishes was highest in the epipelagic zone and within the benthic boundary layer (BBL; 0-200
m above the seafloor) while minimum fish abundance occurred at depths below 2300 m but above the BBL. Biomass per
volume of deep-pelagic fishes over the MAR reached a maximum within the BBL, revealing a topographic association
of a bathypelagic fish assemblage with the mid-ocean ridge system. The dominant component of deep-pelagic fish
biomass over the MAR was a wide-ranging bathypelagic assemblage that was remarkably consistent along the length of
the ridge from Iceland to the Azores. The authors conclude that special hydrodynamic and biotic features of mid-ocean
ridge systems cause changes in the ecological structure of deep-pelagic fish assemblages relative to those at the same
depths over abyssal plains.
Moytirra Vent Field
Due to the unique nature of the Moytirra vent field, the specialized vent fauna associated with it are also unique to the
North Atlantic high-seas area. Wheeler et al. (2013) have documented aggregations of gastropods (Peltospira sp.) and
populations of alvinocaridid shrimp (Mirocaris sp. and Rimicaris sp.) on the surfaces of the vent chimneys in addition to
bythograeid crabs (Segonzacia sp.) and zoarcid fish (Pachycara sp.), all considered hydrothermal vent fauna (van Dover
1995).
Feature condition, and future outlook
Given the geophysical nature, location and size of the MAR it is unlikely that it will be affected by human activities.
Despite its remoteness, the fauna associated with the MAR are not pristine. Starting in the early 1970s with Soviet/Russian
trawlers stocks of roundnose grenadier (Coryphaenoides rupestris), orange roughy (Hoplostethus atlanticus) and
alfonsino (Beryx splendens) associated with the MAR were exploited (Clark et al. 2007, ICES 2007). It can be assumed
that most hills along the ridge were at least explored (usually by midwater trawls operating close to the seafloor), and at
least 30 seamounts were also exploited for C. rupestris. After 1982, the targeted fishery for redfish developed, dwarfing
the catches of roundnose grenadier. After the transition from Soviet to Russian fisheries, the Russian fishing effort and
absolute catch on the MAR was significantly reduced, although catch per fishing day settled at relatively low levels by
the end of 1990s and the fishery was still conducted periodically (ICES 2007). The fishery on C. rupestris takes deepwater
redfish (Sebastes spp), orange roughy (H. atlanticus), blackscabbard fish (Aphanopus carbo) and deepwater sharks as
bycatch (Clark et al. 2007). Longline fishing and near-bottom pelagic trawls have the potential to damage fragile benthic
species such as deep-water corals and sponges. The scale of the impact that fishing and other human activities may have
had on the MAR fauna is at present unquantified. In 2009 NEAFC adopted measures that close more than 330,000 km2
to bottom fisheries on the MAR until 2015 (Figure 4).
According to the International Seabed Authority, exploratory mining for sulfide deposits has already been undertaken on
the MAR, while ferromanganese nodules and cobalt-rich ferromanganese crusts have potential for mining interests. The
potential impacts on the marine environment are removal of organisms and their habitats along with the mineral deposits
and the smothering of adjacent communities by any sediment plume that may be created
(http://www.isa.org.jm/en/about/faqs#16 ).
Representatives from Norway, Iceland, Azores,the United Kingdom, IUCN and UNESCO have met to review the
geological and biological heritage of the MAR in the North Atlantic (http://whc.unesco.org/en/activities/504/ ).
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ICES Advice 2013, Book 1
Discussions focused on the areas where the highest peaks of the mountain chain reach sea-level and form islands. Most
of the underwater ridge was not considered because it lies outside any national territory and therefore is not covered by
provisions of the World Heritage Convention. There was agreement to encourage cooperation with other conventions in
order to better protect the biological, cultural and geological heritage of the ridge.
Assessment against CBD EBSA Criteria
CBD EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
Know
The area contains either (i) unique (“the only one of its
kind”), rare (occurs only in few locations) or endemic
species, populations or communities, and/or (ii) unique,
rare or distinct, habitats or ecosystems; and/or (iii) unique
or unusual geomorphological or oceanographic features
Explanation for ranking
Uniqueness or
rarity
High
X
The Mid-Atlantic Ridge (MAR) qualifies as a unique geomorphological feature in the North Atlantic. The Moytirra vent field is the
only known high temperature hydrothermal vent between the Azores and Iceland, making it a unique geophysical structure in the
high seas of the North Atlantic and within the MAR.
Areas that are required for a population to survive and
Special
importance for thrive
life-history
stages of species
Explanation for ranking
Data deficient
Importance for Area containing habitat for the survival and recovery of
endangered, threatened, declining species or area with
threatened,
endangered or significant assemblages of such species
declining species
and/or habitats
Explanation for ranking
X
X
Data deficient
Areas that contain a relatively high proportion of sensitive
Vulnerability,
habitats, biotopes or species that are functionally fragile
fragility,
sensitivity,
or (highly susceptible to degradation or depletion by human
activity or by natural events) or with slow recovery
slow recovery
Explanation for ranking
X
Deep-water corals were observed at all 8 sites from 3 locations along the proposed EBSA at depths less than 1400 m (range 8002400 m) and 40 coral taxa were observed, including observations of patches of Lophelia pertusa. These taxa are fragile with slow
recovery and highly susceptible to degradation or depletion by human activities including contact with bottom fishing gear
(longlines, pots, trawls).
Area containing species, populations or communities with
Biological
X
comparatively higher natural biological productivity
productivity
Explanation for ranking
The research conducted through the MAR-ECO project found that primary production and export flux over the MAR were not
enhanced compared with a nearby reference station over the Porcupine Abyssal Plain and biomass of benthic macrofauna and
megafauna were similar to global averages at the same depths. There is some evidence for pelagic fish concentrating in the benthic
boundary layer (to 200 m above the seafloor) over the MAR in association with topographic features.
Area contains comparatively higher diversity of
ecosystems, habitats, communities, or species, or has
higher genetic diversity
Explanation for ranking
Biological
diversity
X
Data deficient. Diversity of habitats is greater than that of surrounding abyssal plain but with the exception of the vent fauna,
habitats and species are generally shared with continental margins and seamounts not associated with the MAR.
ICES Advice 2013, Book 1
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Sharing experiences and information applying other international criteria (Optional)
CBD EBSA Criterion
Description
Dependency:
An area where ecological processes are highly dependent
on biotically structured systems (e.g., coral reefs, kelp
forests, mangrove forests, seagrass beds). Such
ecosystems often have high diversity, which is dependent
on the structuring organisms. Dependency also embraces
the migratory routes of fish, reptiles, birds, mammals,
and invertebrates.
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
High
Know
Explanation for ranking
Representativeness:
An area that is an outstanding and illustrative example of
specific biodiversity, ecosystems, ecological or
physiographic processes
Explanation for ranking
Biogeographic
importance:
An area that either contains rare biogeographic qualities
or is representative of a biogeographic “type” or types, or
contains unique or unusual biological, chemical,
physical, or geological features
X
Explanation for ranking
The Mid-Atlantic Ridge (MAR) qualifies as a unique geomorphological feature in the North Atlantic. The Moytirra vent field is the
only known high temperature hydrothermal vent between the Azores and Iceland, making it a unique geophysical structure in the
high seas of the North Atlantic and within the MAR. Fauna endemic to the vents have adapted to the chemical and thermal properties
of the environment.
Structural complexity:
An area that is characterized by complex physical
structures created by significant concentrations of biotic
and abiotic features.
Explanation for ranking
Natural Beauty:
An area that contains superlative natural phenomena or
areas of exceptional natural beauty and aesthetic
importance.
Explanation for ranking
Earth’s geological
history:
An area with outstanding examples representing major
stages of Earth’s history, including the record of life,
significant on-going geological processes in the
development of landforms, or significant geomorphic or
physiographic features.
X
Explanation for ranking
The Mid-Atlantic Ridge is the site of significant on-going geological processes (plate tectonics, formation of new Earth’s crust) and
of significant physiographic features (axial rift valley, hydrothermal vent fields).
[Other relevant
criterion]
Explanation for ranking
[Other relevant
criterion]
Explanation for ranking
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ICES Advice 2013, Book 1
References
Bergstad, O.A., Menezes,G. and Å.S. Høines. 2008. Demersal fish on a mid-ocean ridge: Distribution patterns and
structuring factors. Deep Sea Research Part II: Topical Studies in Oceanography 55(1–2): 185-202.
Bower, A.S., Le Cann, B., Rossby, T., Zenk, W., Gould, J., Speer, K., Richardson, P.L., Prater, M.D. and H.-M. Zhang.
2002. Directly measured mid-depth circulation in the northeastern North Atlantic Ocean. Nature 419: 603- 607.
Clark, M.R., Vinnichencko, V.I., Gordon, J.D.M., Beck-Bulat, G.Z., et al. 2007. Large-scale distant-water trawl fisheries
on seamounts. In: Pitcher, T.J., Morato, T., Hart, P.J.B., Clark, M.R., Haggan, N. and Santos, R.S. (eds)
Seamounts: Ecology, Conservation and Management. Fish and Aquatic Resources Series, Blackwell, Oxford,
UK. Chapter 17, pp. 361 – 399.
Engel, A.E.J. and C.G. Engel. 1964. Composition of basalts from the Mid-Atlantic Ridge. Science 144 (3624): 13301333.
Fossen, I., Cotton, C.F., Bergstad, O.A. and J.E. Dyb. 2008. Species composition and distribution patterns of fishes
captured by longlines on the Mid-Atlantic Ridge. Deep Sea Research Part II: Topical Studies in Oceanography
55(1–2): 203-217.
Gebruk , A.V., Priede, I.G., Fenchel T. and F. Uiblein. 2013. Benthos of the sub-polar front area on the Mid-Atlantic
Ridge: Results of the ECOMAR project. Marine Biology Research 9(5-6): 443-446.
Geistdoerfer, P. 1994. Pachycara thermophilum, une nouvelle espèce de poisson Zoarcidae des sites hydrothermaux de
la dorsale médio-atlantique. Cybium 18: 109-115.
Hareide, N.-R. and G. Garnes. 2001. The distribution and catch rates of deep water fish along the Mid-Atlantic Ridge
from 43 to 61°N. Fisheries Research 51(2–3): 297-310.
Heezen, B.C.,Tharp, M. and M. Ewing. 1959. The Floors of the Oceans: I. The North Atlantic. The Geological Society
of America Special Paper 65, 122 pp.
Heezen, BC. 1969. The world rift system: An introduction to the symposium. Tectonophysics 8:269-279.
ICES. 2007. Report of the Working Group on Deep-water Ecology (WGDEC), 26 – 28th February. ICES CM
2007/ACE:01 Ref. LRC. 61pp.
King, N.J., P.M. Bagley and I.G. Priede. 2006. Depth zonation and latitudinal distribution of deep-sea scavenging
demersal fishes of the Mid-Atlantic Ridge, 42 to 53ºN. Marine Ecology Progress Series 319: 263-274.
Malinverno, A. 1990. A quantitative study of axial topography of the Mid-Atlantic Ridge. Journal of Geophysical
Research 95: 2645-2660.
Mortensen, P.B., Buhl-Mortensen, L., Gebruk, A.V. and E. M. Krylova. 2008. Occurrence of deep-water corals on the
Mid-Atlantic Ridge based on MAR-ECO data. Deep-Sea Research II 55:142-152.
Priede, I.G., Bergstad, O.A., Miller, P.I., Vecchione, M., Gebruk, A., et al. 2013. Does Presence of a Mid-Ocean Ridge
Enhance Biomass and Biodiversity? PLoSONE 8(5): e61550. doi:10.1371/journal.pone.0061550
Rossby, T. 1999. On gyre interactions. Deep-Sea Research II 46: 139-164.
Søiland, H., Budgell, W.P. and Ø Knutsen. 2008. The physical oceanographic conditions along the Mid-Atlantic Ridge
north of the Azores in June-July 2004. Deep-Sea Research II 55: 29- 44.
Speer, K. G. and A. M. Thurnherr. 2005. Abyssal Canyons and Mixing by Low-Frequency Flow. In: P. Muller and D.
Henderson (Editors), Near-Boundary Processes and Their Parameterization, topics in physical oceanography,
'Aha Huliko' a Winter Workshop, pp. 17-19.
Sutton, T.T., Porteiro, F.M., Heino, M., et al. 2008. Vertical structure, biomass and topographic association of deeppelagic fishes in relation to a mid-ocean ridge system. Deep-Sea Research II 55 (1–2):161–184.
Tolstoy, I. and M. Ewing. 1949. North Atlantic hydrography and the Mid-Atlantic Ridge. Bulletin of the Geological
Society of America 60(10): 1527-1540.
van Andel, Tj. H. and C. O. Bowin. 1968. Mid-Atlantic Ridge between 22º and 23º north latitude and the tectonics of
mid-ocean rises. Journal of Geophysical Research 73: 1279-1298.
Van Dover, C.L. 1995. Ecology of Mid-Atlantic Ridge hydrothermal vents. Geological Society, London, Special
Publications 1995, v. 87, p257-294.
Vecchione, M., Young, R.E. and U. Piatkowski. 2010. Cephalopods of the northern Mid-Atlantic Ridge. Marine Biology
Research 6: 25–52.
Wheeler, A.J., Murton, B., Copley, J., Lim, A., Carlsson, J. et al. 2013. Moytirra: discovery of the first known deep-sea
hydrothermal vent field on the slow-spreading Mid-Atlantic Ridge north of the Azores. Geochemistry,
Geophysics, Geosystems, doi: 10.1002/ggge.20243.
White, W.M. and J.-G. Schilling. 1978. The nature and origin of geochemical variation in Mid-Atlantic Ridge basalts
from the Central North Atlantic. Geochimica et Cosmochimica Acta 42 (10): 1501-1516.
ICES Advice 2013, Book 1
163
Tables, Maps and Figures
Table 1
Boundaries for the proposed EBSA Mid-Atlantic Ridge North of the Azores and South of Iceland and
location of the Moytirra Vent Field (see Figure 3).
Feature
Point 1
Point 2
Point 3
Point 4
Point 5
Point 6
EEZ of the Azores
Latitude
63.59
55.85
52.97
52.50
47.11
43.18
Point 7
Point 8
Point 9
Point 10
Point 11
Point 12
EEZ of Iceland
42.50
46.43
49.43
52.50
53.78
60.13
Moytirra Vent Field
164
(dd)
Longitude (dd)
-30.91
-37.51
-36.70
-33.00
-28.09
-30.59
Details of Location
Reference
easterly following
the EEZ boundary
for the Azores to
Point 7
45.4833
-27.55
-25.91
-26.63
-29.80
-33.69
-22.84
-27.85
westerly following
the EEZ boundary
for Iceland to join
Point 1
300 m high fault
scarp of the eastern
axial wall, 3.5 km
from
the
axial
volcanic ridge crest
Wheeler et al. (2013)
ICES Advice 2013, Book 1
Figure 1
Location of the Mid-Atlantic Ridge (dashed lines). Image downloaded from: commons.wikimedia.org
File:Mid-atlantic ridge.jpg - Wikimedia Commons.
ICES Advice 2013, Book 1
165
Figure 2
166
Volcanically heated fluid rises from a deep-sea "black-smoker" in the Moytirra vent field. (Photo
http://news.nationalgeographic.com/news/2011/08/110808-hydrothermal-ventsdownloaded
from
volcanic-animals-ocean-deep-sea-science-alien/ )
ICES Advice 2013, Book 1
Figure 3
Location of the proposed EBSA Mid-Atlantic Ridge North of the Azores and South of Iceland. The perimeter
of the proposed boundary follows Table 1 with points numbered 1 through 12. The blue shaded areas
represent the Exclusive Economic Zones of countries in the region. The light green line outlines the outer
boundary of the OSPAR Convention Area which coincides with the NEAFC Convention Area at its western
and southern boundary. Seafloor bathymetry is indicated in grayscale with the 2000 m (red) and 2500 m
(light blue) General Bathymetric Chart of the Oceans (GEBCO) depth contours indicated. The red circle
with the central star marks the location of the Moytirra Vent Field. See Table 1 for positional information
(latitude and longitude).
ICES Advice 2013, Book 1
167
Figure 4
168
Location of areas closed to bottom fishing (2009-2015) in the NEAFC regulatory area which includes the
MAR http://www.neafc.org/page/closures. There is a small seasonal closure for Blue Ling near the
boundary with Iceland EEZ which is not visible at this scale.
ICES Advice 2013, Book 1
ANNEX 3
Draft Proforma: Charlie-Gibbs Fracture Zone
Presented by: Based on the Joint OSPAR/NEAFC/CBD Scientific Workshop. Reviewed by revised by an ICES expert
group
Abstract
Fracture zones are common topographic features of the global oceans that arise through plate tectonics. The CharlieGibbs Fracture Zone is an unusual left lateral strike-slip double transform fault in the North Atlantic Ocean along which
the rift valley of the Mid-Atlantic Ridge is offset by 350 km near 52º30′N. It opens the deepest connection between the
northwest and northeast Atlantic (maximum depth of approximately 4500 m) and is approximately 2000 km in length
extending from about 25°W to 45°W. It is the most prominent interruption of the MAR between the Azores and Iceland
and the only fracture zone between Europe and North America that has an offset of this size. Two named seamounts are
associated with the transform faults: Minia and Hecate. The CGFZ is considered a unique geomorphological feature in
the North Atlantic under the EBSA criteria; further, it captures the Earth’s geological history, including significant ongoing geological processes.
Introduction
Fracture zones are common topographic features of the global oceans that arise through plate tectonics. They are
characterized by two strongly contrasting types of topography. Seismically active transform faults form near mid-ocean
ridges where the continental plates move in opposing directions at their junction. Seismically inactive fracture zones,
where the plate segments move in the same direction, extend beyond the transform faults often for 100s of kilometers.
Their atypical crust thickness that can be as little as 2 km (Mutter et al. 1984, Cormier et al. 1984, Calvert and Whitmarsh
1986) allowing direct seismic investigations of the internal structure and composition of oceanic crusts used to model
processes of seafloor spreading. In the Atlantic Ocean most fracture zones originate from the Mid-Atlantic Ridge (MAR)
and are nearly perfectly west - east oriented. There are about 300 fracture zones occurring on average every 55 km along
the ridge, with the offsets created by transform faults ranging from 9 to 400 km in length (Müller and Roest 1992).
The Charlie-Gibbs Fracture Zone (CGFZ) is an unusual left lateral strike-slip double transform fault in the North Atlantic
Ocean along which the rift valley of the MAR is offset by 350 km near 52º30′N (Figure 1). It opens the deepest connection
between the northwest and northeast Atlantic (maximum depth of approximately 4500 m; Fleming et al. 1970) and is
approximately 2000 km in length extending from about 25°W to 45°W. It is the most prominent interruption of the MAR
between the Azores and Iceland and the only fracture zone between Europe and North America that has an offset of this
size 11. Knowledge of its geomorphology is considered essential to the understanding of the plate tectonic history of the
Atlantic north of the Azores (Olivet et al. 1974). For these reasons it is consider a unique geomorphological feature in the
North Atlantic under the EBSA criteria; further, it captures the Earth’s geological history, including significant on-going
geological processes.
The CGFZ is comprised of two narrow parallel fracture zones (Fleming et al. 1970) which form deep trenches located at
30ºW (Charlie-Gibbs South Transform Fault) and at 35º15′W (Charlie-Gibbs North Transform Fault) and separated by a
short (40 km) north-south seismically active (Bergman and Solomon 1988) spreading center (median transverse ridge) at
31º45’W (Figure 2; Searle 1981; Fleming et al. 1970, Olivet et al. 1974). The southern fault displaces the MAR, coming
from the Azores, to the west over a distance of 120 km. It is at most 30 km wide (Searle 1981). The northern fault displaces
the spreading ridge over another 230 km to the west before it connects to the northern part of the MAR going to Iceland.
Both transform faults continue eastward and westward as inactive fracture zones (Figure 2).
The CGFZ is characterized by rough morphology and the walls of the fracture valleys and the ridge in between them are
broken and irregular with slopes of up to 29° (Fleming et al. 1970). The height of the ridge between the faults is at least
1000 m below the surface and as shallow as 636 m in parts (Fleming et al. 1970). Rock samples show the walls of the
fracture zone to be both basaltic and ultramafic while the median transverse ridge contains gabbro (Hekinian and Aumento
1973). Earthquake epicentres are associated with the transform faults (Kanamori and Stewart 1976, Bergman and
Solomon 1988) and an almost continuous belt of epicentres follow the southern end of the Reykjanes Ridge, along the
northern transform valley, the central median valley and the southern transform valley to the north end of the MAR
(Lilwall and Kirk 1985). Two named seamounts are associated with the transform faults: Minia Seamount (53°01′N
34°58′W) located near the junction of the Reykjanes Ridge and the northern transform fault and Hecate Seamount
11
The Spitzbergen and Jan Mayen fracture zones, of comparable offset (145 and 211 km respectively), lie between Greenland and Europe.
ICES Advice 2013, Book 1
169
(52°17′N 31°00′W) located on the northern wall of the southern transform fault east of the short median transverse ridge
(Figure 2; Fleming et al. 1970).
Ridge and troughs along the CGFZ are mostly covered with muddy sediments (Fleming et al. 1970) although outcrops of
sedimentary rock and boulder fields are exposed by recent faulting and current scour (Shor et al. 1980, Searle 1981) and
the southern transform near 30°30′W has no sediment cover (Searle 1981). Considerable thicknesses of sediment are
deposited in the northern transform valley from the Iceland-Scotland Overflow Water (ISOW) which carries a significant
load of suspended sediment (25 μg I-1) as it passes through (Shor et al. 1980). Transverse ridges prevent the sediment
reaching the southern valley (Searle 1981) which has less sediment cover, although it is still considered a depositional
environment (Shor et al. 1980).
The topography of the CGFZ has a major influence on deep water oceanographic circulation (Harvey and Theodorou
1986). A large component of the North Atlantic Deep Water originates in the Norwegian Sea and flows south over the
sills between Scotland and Iceland (ISOW). It meets the CGFZ near the intersection of the transform faults and the
spreading centre (Shor et al. 1980). There is then a westward movement of deep water passing through the fracture zone
from east to west through to the Irminger Sea occurring from the core depth of the ISOW at about 2500 m to the sea floor
(Garner 1972, Shor et al. 1980, Saunders 1994). Most of this water is carried through the northern transform fault where
the overflow water first encounters the fracture zone.
The topography of the CGFZ also is thought to have some influence on the circulation of surface waters, although they
are not locked to the bottom features to the same extent as the ISOW (Rossby 1999, Bower et al. 2002). The northern
branch of the North Atlantic Current defines the location of the sub-polar front between colder Sub Arctic Intermediate
Water to the north and warmer North Atlantic Intermediate Water to the south (Søiland et al. 2008). The sub-polar front
meanders between 48-53°N and surface flow is predominantly eastward. The CGFZ is therefore not only a topographic
discontinuity in the MAR but the area also constitutes an oceanographic transition zone between waters of different
temperatures and flow regimes (Priede et al. 2013).
Location
The Charlie-Gibbs Fracture Zone occurs at 52º30′N and extends from about 25°W to 45°W with the transform faults
occurring between 30°W and 35°W (Olivet et al. 1974). The proposed Charlie-Gibbs Fracture Zone EBSA within the
high-seas area of NEAFC and OSPAR takes the co-ordinates provided in Table 1 and illustrated in Figure 3. These are
based on Olivet et al. (1974) and the location of the Minia Seamount which influences the northern boundary of the
EBSA. The eastern boundary of the CGFZ is detectable beyond 42°W, the outer boundary of the NEFAC/OSPAR
jurisdictions. The southern ridge continues uninterrupted to 45°W (Olivet et al. 1974).
Feature description
The Charlie-Gibbs Fracture Zone (CGFZ) is a unique geomorphological feature to the North Atlantic Ocean and to the
high-seas areas of NEAFC and OSPAR. Owing to its remoteness, the fauna associated with the CGFZ are poorly studied
and it is premature to speculate on whether any species are endemic based on first descriptions. For example, Gebruk
(2008) described two species of holothurians and believed them to be endemic to the Mid-Atlantic Ridge but they
subsequently were found on the European continental margin in the Whittard Canyon (Masson 2009).
As part of the MAR-ECO project (Priede et al. 2013) manned submersibles were deployed on the axis (52°47′N) and the
northern slopes (52°58′N) of the Charlie–Gibbs North transform fault and surveyed macroplankton (Vinogradov 2005),
demersal nekton (Felley et al. 2008) and invertebrate megafauna (Gebruk and Krylova 2013). Pelagic shrimps,
chaetognaths and gelatinous animals were numerically dominant in the plankton, with peak densities corresponding to
the main pycnocline. Mucous houses of appendicularians were abundant at 150 m above the seabed, although this is
common throughout the central Atlantic and not associated with specific bottom topography (Vinogradov 2005). Nekton
included large and small macrourids (Coryphaenoides spp.), shrimp (infraorder Penaeidea), Halosauropsis macrochir,
Aldrovandia sp., Antimora rostrata, and alepocephalids (Felley et al. 2008).
Glass sponges were common between 1700 and 2500 m while the deeper parts of the fracture wall and the sea floor were
dominated by isidid corals, other anthozoans, squat lobsters and echinoderms, especially holothurians. The elpidiid
holothurian, Kolga nana, occurred at high density in the abyssal depression (Gebruk and Krylova 2013). Rogacheva et
al. (2013) recorded 32 holothurian species from the CGFZ area through the ECOMAR project
(http://www.oceanlab.abdn.ac.uk/ecomar/), including three elasipodid holothurian species new to science.
In general, none of the fauna documented from the CGFZ showed distributions atypical of similar habitats in the broader
North Atlantic, although Gebruk and Krylova (2013) discuss the known distribution of the holothurian Peniagone
longipaillata and remark on the differences in relative abundance observed between the occurrence of this species, where
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ICES Advice 2013, Book 1
it is common in the lower bathyl of the CGFZ, and the continental slopes in the Porcupine Seabight and Abyssal Plain
areas and Whitard Canyon where it appears less so. There is weak evidence that the CGFZ may be important for juvenile
zoarcids based on a high percentage of those observed with baited cameras being <100 mm in length (Kemp et al. 2013).
General knowledge of seafloor benthos suggests that where the geo-morphological processes of the fracture zone have
created steep walls along the fractures, the greater three-dimensional topographic complexity, combined with the strong
water flows through the fractures, creates habitat that is likely to be more productive and support greater concentrations
of fragile taxa such as deep-water corals and sponges than adjacent habitats (Miller et al. 2012). The sampling done
along the fracture zone supports these inferences but the differences from other habitats in similar depths and latitudes
have not been quantified yet.
Feature condition, and future outlook
Given the geophysical nature, location and size of the Charlie-Gibbs Fracture Zone (CGFZ) it is unlikely that it will be
affected by human activities, although there is potential for mining of the rare minerals associated with the transform
faults. In 2010 the Environmental Ministers of the OSPAR countries officially designated a marine protected area of
145,420 km2 in the southern part of the Charlie-Gibbs Fracture Zone (Figure 4) and adopted “significant and innovative
measures to establish and manage the southern part of the originally proposed Charlie-Gibbs Fracture Zone MPA –
“Charlie-Gibbs South MPA”-, for which the seabed and super adjacent waters are situated in areas beyond national
jurisdiction” (OSPAR Commission 2010). That same year (2010) the OSPAR Commission and the International Seabed
Authority signed a memorandum of understanding in order to conciliate the development of mineral resources with
comprehensive protection of the marine environment. In this MOU, the Charlie Gibbs Fracture Zone is highlighted as an
area where consultation between the two parties had been initiated. In 2012 OSPAR countries designated “ Charlie-Gibbs
North High Seas Marine Protected Area”, an area of high seas of approximately 177,700 km2 (OSPAR Commission
2012), complementing the Charlie-Gibbs South MPA established previously (Figure 4).
The scale of the impact that fishing and other human activities have had on the fauna of the CGFZ is at present
unquantified and likely to be minor, although fishing has been reported on the Hectate Seamount (ICES 2007). In 2009
NEAFC closed more than 330,000 km2 to bottom fisheries on the Mid-Atlantic Ridge, including a large section of the
CGFZ which includes the transform faults and median transverse ridge (http://www.neafc.org/page/closures) (Figure 4).
Assessment against CBD EBSA Criteria
[Discuss the case study in relation to each of the CBD criteria and relate the best available science. Note that a candidate
EBSA may qualify on the basis of one or more of the criteria, the boundaries of the EBSA need not be defined with exact
precision. And modeling may be used to estimate the presence of EBSA attributes. Please note where there are significant
information gaps.]
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
Know
The area contains either (i) unique (“the only one of its
kind”), rare (occurs only in few locations) or endemic
species, populations or communities, and/or (ii) unique,
rare or distinct, habitats or ecosystems; and/or (iii) unique
or unusual geomorphological or oceanographic features
Explanation for ranking
Uniqueness
rarity
or
High
X
The Charlie-Gibbs Fracture Zone (CGFZ) is a unique geomorpholical feature in the high-sea between the Azores and Iceland. It is
the only fracture zone with an offset of its size (350 km) between Europe and North America and opens the deepest connection
between the northwest and northeast Atlantic. The fact that it is a double transform fault is an unusual feature.
Areas that are required for a population to survive and
Special
importance for thrive
life-history
stages of species
Explanation for ranking
X
Data deficient
ICES Advice 2013, Book 1
171
Importance for Area containing habitat for the survival and recovery of
endangered, threatened, declining species or area with
threatened,
endangered or significant assemblages of such species
declining species
and/or habitats
Explanation for ranking
X
Data deficient
Areas that contain a relatively high proportion of sensitive
Vulnerability,
habitats, biotopes or species that are functionally fragile
fragility,
sensitivity,
or (highly susceptible to degradation or depletion by human
activity or by natural events) or with slow recovery
slow recovery
Explanation for ranking
X
Glass sponges were observed on hard substrates on the fault wall at depths between 1700 and 2500 m. These taxa are fragile with
slow recovery and highly susceptible to degradation or depletion by human activities including contact with bottom fishing gear
(longlines, pots, trawls).Inferring from the frequently documented presence of such species and communities in structurally complex
deep-sea habitats elsewhere, further sampling is likely to document additional presence of sensitive habitats, biotopes, or species in
the CGFZ fractures,
Area containing species, populations or communities with X
Biological
comparatively higher natural biological productivity
productivity
Explanation for ranking
There is no evidence that the CGFZ contains comparatively higher natural productivity. The strong current flows through the
fractures and complex three dimensional habitats create conditions that may enhance productivity, but at present there are
insufficient data to rank on this criterion.
Area contains comparatively higher diversity of
Biological
X
ecosystems, habitats, communities, or species, or has
diversity
higher genetic diversity
Explanation for ranking
Diversity of habitats is greater than that of surrounding abyssal plain but biotic diversity is poorly quantified and there is little basis
for a comparative assessment on this criterion at this time.
Sharing experiences and information applying other international criteria (Optional)
CBD EBSA Criterion
Description
Dependency:
An area where ecological processes are highly dependent
on biotically structured systems (e.g., coral reefs, kelp
forests, mangrove forests, seagrass beds). Such
ecosystems often have high diversity, which is dependent
on the structuring organisms. Dependency also embraces
the migratory routes of fish, reptiles, birds, mammals,
and invertebrates.
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
High
Know
Explanation for ranking
Representativeness:
An area that is an outstanding and illustrative example of
specific biodiversity, ecosystems, ecological or
physiographic processes
Explanation for ranking
Biogeographic
importance:
An area that either contains rare biogeographic qualities
or is representative of a biogeographic “type” or types, or
contains unique or unusual biological, chemical,
physical, or geological features
X
Explanation for ranking
The CGFZ qualifies as a unique geomorphological feature in the North Atlantic being the largest transform fault separating Europe
from North America.
An area that is characterized by complex physical
Structural complexity:
structures created by significant concentrations of biotic
and abiotic features.
Explanation for ranking
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ICES Advice 2013, Book 1
Natural Beauty:
An area that contains superlative natural phenomena or
areas of exceptional natural beauty and aesthetic
importance.
Explanation for ranking
Earth’s geological
history:
An area with outstanding examples representing major
stages of Earth’s history, including the record of life,
significant on-going geological processes in the
development of landforms, or significant geomorphic or
physiographic features.
X
Explanation for ranking
Fracture zones are of great geological interest due to their anomalous crust thickness that can be as little as 2 km allowing direct
seismic investigations of the internal structure and composition of oceanic crusts used to model processes of seafloor spreading.
Knowledge of the geomorphology of the CGFZ is considered essential to the understanding of the plate tectonic history of the
Atlantic north of the Azores.
[Other relevant
criterion]
Explanation for ranking
[Other relevant
criterion]
Explanation for ranking
References
Bergman, E.A. and S.C. Solomon. 1988. Transform fault earthquakes in the North Atlantic: Source mechanisms and
depth of faulting. Journal of Geophysical Research 93:9027-9057.
Bower, A.S., Le Cann, B., Rossby, T., Zenk, W., Gould, J., Speer, K., Richardson, P.L., Prater, M.D. and H.-M. Zhang.
2002. Directly measured mid-depth circulation in the northeastern North Atlantic Ocean. Nature 419: 603- 607
Calvert, A.J. and R.B. Whitmarsh. 1986. The structure of the Charlie-Gibbs Fracture Zone. Journal of the Geological
Society 1433: 819-821.
Cormier, M.-H., Detrick, R. S. and G. M. Purdy. 1984. Anomalously thin crust in oceanic fracture zones: New seismic
constraints from the Kane Fracture Zone. Journal of Geophysical Research 89:249–266.
Felley, J.D., Vecchione, M. And R.R. Wilson Jr. 2008. Small-scale distribution of deep-sea demersal nekton and other
megafauna in the Charlie-Gibbs Fracture Zone of the Mid-Atlantic Ridge. Deep Sea Research II 55: 153-160.
Fleming, H.S., Cherkis, N.Z. and J.R. Heirtzler. 1970. The Gibbs Fracture Zone: A double fracture zone at 52°30′N in
the Atlantic Ocean. Marine Geophysical Researches 1:37-45.
Garner, D.M. 1972. Flow through the Charlie-Gibbs Fracture Zone, Mid-Atlantic Ridge. Canadian Journal of Earth
Sciences 9: 116-121.
Gebruk A.V. 2008. Holothurians (Holothuroidea, Echinodermata) of the northern Mid-Atlantic Ridge collected by the
G.O. Sars MAR-ECO expedition with descriptions of four new species. Marine Biology Research 4, 48–60.
Gebruk, A.V. and E.M. Krylova. 2013. Megafauna of the Charlie–Gibbs Fracture Zone (northern Mid-Atlantic Ridge)
based on video observations. Journal of the Marine Biological Association of the United Kingdom 93: 1143-1150.
doi:10.1017/S0025315412001890.
Harvey, J.G. and A. Theodorou. 1986. The circulation of Norwegian Sea overflow water in the eastern North Atlantic.
Oceanologica Acta 9: 393-402.
Hekinian, R. and F. Aumento. 1973. Rocks from the Gibbs Fracture Zone and the Minia Seamount near 53°N in the
Atlantic Ocean. Marine Geology 14: 47-72.
ICES. 2007. Report of the Working Group on Deep-water Ecology (WGDEC), 26 – 28th February. ICES CM
2007/ACE:01 Ref. LRC. 61pp.
Kanamori, H. and G.S. Stewart. 1976. Mode of the strain release along the Gibbs Fracture Zone, Mid-Atlantic Ridge.
Physcis of the Earth and Planetary Interiors 11: 312-332.
Kemp, K.M., Jamieson, A.J., Bagley, P.M., Collins, M.A. and I.G. Priede. 2008. A new technique for periodic bait release
at a deep-sea camera platform: First results from the Charlie-Gibbs Fracture Zone, Mid-Atlantic Ridge. Deep-Sea
Research II 55: 218-228.
Lilwall, R.C. and R.E. Kirk. 1985. Ocean-bottom seismograph observations on the Charlie-Gibbs fracture zone.
Geophysical Journal of the Royal Astronomical Society 80: 195-208.
Masson, D.G. 2009. The Geobiology of Whittard Submarine Canyon. RRS James Cook Cruise 36, 19 June–28 July 2009.
National Oceanography Centre, Southampton, 53 pp. http://www.eprints.soton.ac.uk/69504/1/nocscr041.pdf.
ICES Advice 2013, Book 1
173
Miller, R.J., Hocevar, J., Stone, R.P. and D.V. Fedorov. 2012. Structure-forming corals and sponges and their use as fish
habitat in Bering Sea submarine canyons. PLoS ONE 7(3): e33885. doi:10.1371/journal.pone.0033885
Müller, R.D. and W.R. Roest. 1992. Fracture zones in the North Atlantic from combined Geosat and Seasta data. Journal
of Geophysical Research 97: 3337-3350.
Mutter, J.C., Detrick, R.S. and North Atlantic Transect Study Group. 1984. Multichannel seismic evidence for
anomalously thin crust at Blake Spur fracture zone. Geology 12: 534-537.
Olivet, J.-L., Le Pichon, Xl, Monti, S. and B. Sichler. 1974. Charlie-Gibbs Fracture Zone. Journal of Geophysical
Research 79: 2059-2072.
OSPAR Commission. 2010. OSPAR Convention for the Protection of the Marine Environment of the North-East Atlantic.
Meeting of the OSPAR Commission Bergen: 20-24 September 2010. Annex 49 (Ref. M6.2).
http://www.ospar.org/content/content.asp?menu=01441000000000_000000_000000
OSPAR Commission. 2012. OSPAR Convention for the Protection of the Marine Environment of the North-East Atlantic.
Meeting of the OSPAR Commission Bonn: 25-29 June 2012. Annex 6 (Ref. §5.19a). OSPAR Decision 2012/01.
Priede, I.G., Billett, D.S.M., Brierley, A.S., Hoelzel, A.R., Inall, M., Miller, P.I., Cousins, N.J., Shields, M.A. and T.
Fujii. 2013. The ecosystem of the Mid-Atlantic Ridge at the sub-polar front and Charlie-Gibbs Fracture Zone;
ECO-MAR project strategy and description of the sampling programme 2007-2010. Deep-Sea Research II
http://dx.doi.org/10.1016/j.dsr2.2013.06.012i.
Rogacheva A, Gebruk A. and C.Alt. 2013. Deep-sea holothurians of the Charlie Gibbs Fracture Zone area, northern MidAtlantic Ridge. Marine Biology Research 9:587_623.
Rossby, T. 1999. On gyre interactions. Deep-Sea Research II 46: 139-164.
Saunders, P.M. 1994.The flux of overflow water through the Charlie–Gibbs Fracture Zone. Journal of Geophysical
Research 99:12343–12355.
Searle, R. 1981. The active part of the Charlie-Gibbs Fracture Zone: A study using sonar and other geophysical
techniques. Journal of Geophysical Research 86: 243-262.
Shor, A., Lonsdale, P., Hollister, C.D. and D. Spencer. 1980. Charlie-Gibbs fracture zone: bottom-water transport and its
geological effects. Deep-Sea Research 27A: 325-245.
Søiland, H., Budgell, W.P. and Ø Knutsen. 2008. The physical oceanographic conditions along the Mid-Atlantic Ridge
north of the Azores in June-July 2004. Deep-Sea Research II 55: 29- 44.
Vinogradov, G.M. 2005. Vertical distribution of macroplankton at the Charlie-Gibbs Fracture Zone (North Atlantic), as
observed from the manned submersible “Mir-1”. Marine Biology 146: 325-331.
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Tables, Maps and Figures
Table 1.
Boundaries for the proposed EBSA Charlie-Gibbs Fracture Zone and location of the Minia and Hecate
Seamounts (see Figure 3).
Feature
CGFZ Proposed EBSA
Point 1
CGFZ Proposed EBSA
Point 2
CGFZ Proposed EBSA
Point 3
CGFZ Proposed EBSA
Point 4
CGFZ Proposed EBSA
Point 5
Northern
Fracture
(eastern portion)
Southern Fracture
(eastern portion)
Northern
Fracture
(western portion)
Southern Fracture
(western portion)
Minia Seamount
Hecate Seamount
ICES Advice 2013, Book 1
Latitude
(dd)
Longitude
(dd)
51°N
42°W
53°05′N
42°W
53°05′N
30°W
52°30′N
25°W
51°45′N
25°W
53°05′N
42°W
51°N
45°W
52°30′N
27°W
51°45′N
25°W
53°01′N
34°58′W
53º 00.60' N
34º 49.80' W
52°17′N
31°00′W
52º 15.60' N
31º 03.00' W
Details
Location
of
Reference
Olivet
8)
Olivet
8)
Olivet
11)
Olivet
11)
located near the
junction of the
Reykjanes Ridge
and the northern
transform fault
et al. 1974 (p. 2062, fig.
et al. 1974 (p. 2062, fig.
et al. 1974 (p. 2063, fig.
et al. 1974 (p. 2064, fig.
Fleming et al. 1970
Seamount Catalogue
http://earthref.org/SC/SMNT530N-0348W/
located on the
northern wall of
the
southern
transform fault east
of the short median
transverse ridge
Fleming et al. 1970
Seamount Catalogue
http://earthref.org/SC/SMNT530N-0348W/
175
Figure 1
176
Location of the Charlie-Gibbs Fracture Zone (black lines) in the North Atlantic. The Mid-Atlantic Ridge
runs through the centre of the Atlantic Ocean and its left lateral displacement can be clearly seen. Image
downloaded from: commons.wikimedia.org File:Charlie-gibbs-full-extent.png - Wikimedia Commons.
ICES Advice 2013, Book 1
Figure 2
Schematic of the Charlie-Gibbs Fracture Zone and the Mid-Atlantic Ridge (MAR) indicating the
left lateral displacement of the MAR, the North and South transform faults and the central spreading
axis. The relative location of two seamounts, Hecate and Minia are illustrated. Image downloaded
from: commons.wikimedia.org File:Charliegibbsschema-en.svg- Wikimedia Commons.
Figure 3.
Proposed Charlie-Gibbs Fracture Zone EBSA (yellow lines). Numbers refer to the points in Table 1. The
green line is the NEAFC/OSPAR outer boundary.
ICES Advice 2013, Book 1
177
Figure 4.
178
Location of the OSPAR MPAs in the North Atlantic including the large Charlie-Gibbs South and CharlieGibbs North MPAs in the central area. The areas closed to bottom fishing by NEAFC are indicated by the
yellow boundaries. Downloaded 10 Sep 2013 from: http://charlie-gibbs.org/charlie/node/70
ICES Advice 2013, Book 1
ANNEX 4
Draft Proforma - The Arctic Ice habitat - multiyear ice, seasonal ice and- marginal ice zone
Presented by WWF and reviewed by Participants at the Joint OSPAR/NEAFC/CBD Scientific Workshop on the
Identification of Ecologically or Biologically Significant Marine Areas in the North-East Atlantic. Reviewed and revised
by an ICES expert group.
Abstract
The permanently ice covered waters of the high Arctic provide a range of globally unique habitats associated with the
variety of ice conditions. In the northern hemisphere multi-year sea ice only exists in the Arctic and although the
projections of changing ice conditions due to climate change project a considerable loss of sea ice, in particular multiyear
ice, the Eurasian Central Arctic high seas are likely to at least keep the ice longer than many other regions in the Arctic
basin. Ice is a crucial habitat and source of particular food web dynamics, the loss of which will affect also a number of
mammalian and avian predatory species. The particularly pronounced physical changes of Arctic ice conditions as already
observed and expected for the coming decades, will require careful ecological monitoring. Eventually measures will be
needed to maintain or restore, to the extent possible the resilience of the Arctic populations to changing environmental
conditions.
Introduction
Over many past millennia, most of the Eurasian part of the Arctic Basin, and in particular the high seas area in the Arctic
Ocean (the waters beyond the 200 nm zones of coastal states, i.e. Norway, Russia, USA, Canada and Greenland/Denmark)
have been permanently ice covered. However, in recent years, much of the multiyear permanent pack ice has been
replaced by seasonal (1 year) ice. In addition, the former fast pack-ice is now increasingly broken up by leads. This
structural change in the Arctic ice quality will result in a substantial increase in light penetrating the thin ice and water
column, in conjunction with the overall warming of surface waters and increased temperature and salinity stratification
due to the melting of ice.
Some models predict that before the end of the century the permanent ice cover may disappear completely (Anisimov et
al., 2007). The reduction and possible loss of permanent ice cover will result in significant changes in the structure and
dynamics of the high Arctic ecosystems (CAFF, 2010; Gradinger, 1995; Piepenburg, 2005; Renaud et al., 2008;
Wassmann, 2008, 2011).
Understanding and studying the area proposed as EBSA is of particular scientific relevance as already envisaged by the
Arctic Council (Gill et al., 2011; Mauritzen et al., 2011). Such studies may in the long-term, become relevant for the
commercial exploitation of resources.
Location
The Ecologically or Biologically Significant Marine Area (EBSA) proposed focuses on the presently permanently icecovered waters in the OSPAR/NEAFC maritime areas, including the high seas section in the Central Arctic Basin north
of the 200 nm zones of coastal states, and the area of contiguous seasonal ice directly connected to the multi-year
permanent ice (see Fig. 1 attached). Therefore, the boundaries proposed extend from the North Pole (northernmost point
of OSPAR/NEAFC maritime areas) to the southern limit of the summer sea ice extent and marginal ice zone, including
on the shelf of East Greenland.
The proposal currently only relates to features of the water column and the ice surface itself. Two legal states have to be
distinguished: the Central Arctic high seas waters north of the 200 nm zones of adjacent coastal states, generally north of
84° N, and the waters within the Exclusive Economic Zones of Greenland, Russia and the fisheries protection zone of
Norway around Svalbard. Figure 1 distinguishes between the high seas beyond national jurisdiction for which the ”Joint
OSPAR/NEAFC/CBD Scientific Workshop on the Identification of Ecologically or Biologically Significant Marine
Areas (EBSAs) in the North-East Atlantic“ had a mandate12 and national/nationally administered waters within the 200
nm zone (national EEZs), within which the OSPAR Contracting Parties have the competence to report candidate EBSAs
to the Convention on Biodiversity EBSA repository (OSPAR Commission, 2011).
Participant Briefing for a Joint OSPAR/NEAFC/CBD Scientific Workshop on the Identification of Ecologically or
Biologically Significant Marine Areas (EBSAs) in the North-East Atlantic. Invitation Annex 2, 2011
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179
The seafloor of the respective region will likely fall on the extended continental shelves of several coastal states. It belongs
to the ”Arctic Basin“ region of (Gill et al., 2011). Seafloor features were not considered in this assessment.
Figure 1 shows the location of the Arctic Ice „Ecologically or Biologically Significant Area“ (EBSA) proposed.
Feature description
The Ecologically or Biologically Significant Marine Area (EBSA) proposed focusses on the presently permanently icecovered waters in the OSPAR/NEAFC maritime areas, including the high seas section in the Central Arctic Basin north
of the 200 nm zones of coastal states, and the marginal ice zone (where the ice breaks up, also called seasonal ice zone)
along its southern margins (see Fig. 1 attached). Due to the inflow of Atlantic water along the shelf of Svalbard, and the
concurrent outflow of polar water and ice on the Greenland side of Fram Strait, the southern limit of the summer sea ice
extent is much further south in the western compared to the eastern Fram Strait, and in former times extended all along
the Greenland coast.
Several of the key ecosystem functions and species dependencies are associated with the ice front. Statements made
about those functions and dependencies apply to the area where the front is located at any particular time of the year, and
not necessarily to either areas fully ice covered (permanently or seasonally) or open waters distant from the ice front in
summer.
The high seas section of the OSPAR maritime area in the Central Arctic ocean is generally north of 84° N and much is
fully ice-covered also in summer, although the quantity of multiyear ice has already substantially decreased and the 1year ice leaves increasingly large leads and open water spaces. The ice overlays a very deep water body of up to 5000 m
depth distinct from the surrounding continental shelves and slopes of Greenland and the Svalbard archipelago. The
Nansen-Gakkel Ridge, a prolongation of the Mid-Atlantic Ridge north of the Fram Strait is structuring the deep Arctic
basin in this section, separating the Central Nansen Basin to the south from the Amundsen Basin to the north. Abundant
hydrothermal vent sites have been discovered on this ridge at about 85° 38 N (Edmonds et al., 2003).
North of Spitsbergen, the Atlantic water of the West Spitsbergen Current enters the Arctic basin as a surface current. At
around 83° N, a deep-reaching frontal zone separates the incoming Atlantic and shelf waters from those of the Central
Nansen Basin (Anderson et al., 1989), a transition reflected in ice properties, nutrient concentrations, zooplankton
communities, and benthic assemblages (Hirche and Mumm, 1992, and literature quoted). This water subsequently
submerges under the less dense (less salinity, lower temperature) polar water and circulates, in opposite direction to the
surface waters and ice, counterclockwise along the continental rises until turning south along the Lomonossov Ridge and
through Fram Strait as East Greenland Current south to Danmark Strait (Aagaard, 1989; Aagaard et al., 1985). Connecting
the more fertile shelves with the deep central basin, these modified Atlantic waters supply the waters north of the NansenGakkel Ridge, in the Amundsen basin, with advected organic material and nutrients which supplement the autochtonous
production (Mumm et al., 1998). Due to the import of organic biomass from the Greenland Sea and the Arctic continental
shelves, part of which may not be kept in the food web due to the polar conditions, the Arctic Ocean may also represent
an enormous carbon sink (Hirche and Mumm, 1992).
In the Fram Strait, the region between Svalbard to the east and Greenland to the west, the East Greenland Current is the
main outflow of polar water and ice from the Arctic Basin (Maykut, 1985) (Aagaard and Coachman, 1968). The polar
front (0° C isotherm and 34.5 isohaline at 50 m depth) extends approximately along the continental shelf of Greenland,
separating the polar surface water from the Arctic (Intermediate) water and the marginal ice zone to the east (e.g. Aagaard
and Coachman, 1968; Paquette et al., 1985). The ice cover is densest in polar water, its extent to the east depends on the
wind conditions (compare also Angelen et al., 2011; Wadhams, 1981).
The seasonal latitudinal progression of increasing and diminishing light levels, respectively, is the determining factor for
the timing of the phytoplankton-related pelagic production. Therefore, the spring bloom and ice break up progress from
south to north in spring, reaching the Arctic area by about June/July. Because the currents in Fram Strait move in opposite
direction, the polar East Greenland Current to the south, and the Atlantic West Spitsbergen Current to the north, there is
a delay of about a month between biological spring and summer between the polar and the Atlantic side (Hirche et al.,
1991). Therefore, sea ice and the effect of melting ice are important determinants of the ecosystem processes all along
the East Greenland polar front from the Greenland Sea through Fram Strait to the Arctic Basin (Legendre et al., 1992;
Wassmann, 2011).
Ice situation
The Arctic Ocean is changing towards a one-year instead of a multi-year sea-ice system with consequences for the entire
ecosystem, including ecosystem shifts, biodiversity changes, water mass modifications, and role in the global overturning
circulation. At its maximum, sea-ice covers 4.47 million km² in the Arctic Basin (Gill et al., 2011): According to data
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from ice satellite observations in 1973-76 (NASA, 1987, in (Gill et al., 2011)), permanent ice occupied 70-80% of the
Arctic Basin area, and the inter-annual variability of this area did not exceed 2%. Seasonal ice occupied 6-17% (before
the melting period of the mid-1970s). By the end of the first decade of the 21st century, the permanent-ice area had
decreased greatly, concurrent with a rapid increase in seasonal- ice. Whereas multiyear ice used to cover 50-60% of the
Arctic, it covered less than 30% in 2008, after a minimum of 10% in 2007. The average age of the remaining multiyear
ice is also decreasing from over 20 % being at least six years in the mid- to late 1980s, to just 6% of ice six years old or
older in 2008.
Figure 2: Modelled ice age distribution in 1985-2000 (left) compared to February 2008 (right) (CAFF, 2010).
This trend is likely to amplify in the coming years, as the net ocean-atmosphere heat output due to the current anomalously
low sea ice coverage has approximately tripled compared to previous years, suggesting that the present sea ice losses have
already initiated a positive feedback loop with increasing surface air temperatures in the Arctic (Kurtz et al., 2011).
About 10% of the sea ice in the Arctic basin is exported each year through Fram Strait into the Greenland Sea (Maykut,
1985) which is therefore major sink for Arctic sea ice (Kwok, 2009). From 2001 to 2005, the summer ice cover was so
low on the East Greenland shelf, that it was more of a marginal ice zone (Smith Jr and Barber, 2007). However the
subsequent record lows in overall Arctic ice cover brought about an increase in ice cover off Greenland, which minimised
the extent of the North East Water Polynia on the East Greenland shelf13, a previously seasonally ice-free stretch of water
(Wadhams, 1981).
Ice related biota
An inventory of ice-associated biota covering the entire Arctic presently counts over 1000 protists, and more than 50
metazoan species (Bluhm et al., 2011). The regionally variable ice fauna (dependent on, inter alia, ice age, thickness,
origin) consists of sympagic biota living within the caverns and brine channels of the ice, and associated pelagic fauna.
The most abundant and diverse sympagic groups of the ice mesofauna in the Arctic seas are amphipods and copepods.
Polar cod (Boreogadus saida) and to a lesser extent Arctic cod (Arctogadus glacialis) are dependent on the sympagic
macro- and mesofauna for food. The fish themselves are important food sources for Arctic seals (such as ringed seal
Phoca hispida) and birds, for example black guillemots Cephus grylle (Bradstreet and Cross, 1982; Gradinger and Bluhm,
2004 and literature reviewed; Horner et al., 1992; Süfke et al., 1998).
The higher the light level in the ice, the higher is the biomass of benthic algae as well as meiofauna and microorganisms
within the ice (Gradinger et al., 1991). Decreasing snow cover induces a feedback loop with enhanced algal biomass
increasing the heat absorption of the ice which leads to changes in the ice structure, and ultimately the release of algae
from the bottom layer (Apollonio, 1961 in Gradinger et al., 1991). Because of the distance to land and shelves, and the
thickness and internal structure of the multiyear pack ice over deeper water, this type of ice has a fauna of its own (Carey,
1985; Gradinger et al., 1991). Arctic multiyear ice floes can have very high algal biomasses in the brine channels and in
the bottom centimeters which serves as food for a variety of proto- and metazoans, usually smaller than 1 mm, over deep
water (Gradinger et al., 1999). In the central Arctic, ice algal productivity can contribute up to 50 % of the total primary
productivity, with lower contributions in the sea ice covered margins (Bluhm et al., 2011).
In the boundary layer between ice floes and the water column, another specific community exists which forms the link
between the ice based primary production and the pelagic fauna (Gradinger, 1995). Large visible bands of diatoms hang
down from the ice, and are exploited by amphipods such as Gammarus wilkitzki, and occasionally by water column
copepods such as Calanus glacialis, which are important prey of for example polar cod Boreogadus saida. The caverns,
wedges and irregularities of the ice provide important shelter from predators for larger ice associated species and provide
an essential habitat for these species (Gradinger and Bluhm, 2004).
During melt, the entire sympagic ice biota are released into the water column where they may initiate the spring algal
plankton bloom (Smith and Sakshaug, 1990) or they may sink to the sea floor and serve as an episodic and first food pulse
for benthic organisms before pelagic production begins (Arndt and Pavlova, 2005). In particular the shallow shelves and
the shelf slope benthos has been shown to profit of this biomass input, reflected in very rich benthic communities
(Klitgaard and Tendal, 2004; Piepenburg, 2005).
The role of the polar front and marginal ice zone for the production system
Primary production in the Arctic Ocean is primarily determined by light availability, which is a function of ice thickness,
ice cover, snow cover, light attenuation), the abundance of both ice algae and phytoplankton, nutrient availability and
surface water stratification. Generally, the spring bloom occurs later further north and in regions with a thick ice and snow
13
http://www.issibern.ch/teams/Polynya/
ICES Advice 2013, Book 1
181
cover. The current production period in the Arctic Ocean may extend to 120 days per year, with a total annual primary
production in the central Arctic Ocean of probably up to 10 g C m-2 (Wheeler et al., 1996).
Ice algae start primary production when light levels are relatively low, as melting reduces the thickness of the ice and
snow cover. The major phytoplankton bloom develops only after the ice breaks up, when melting releases the ice biota
into the water column and meltwater leads to surface stratification. The bloom lasts a few weeks, fuelling the higher
trophic food web of the Arctic (Gradinger et al., 1999, and literature quoted).
The marginal ice zones, i.e. where the ice gets broken up in warmer Atlantic or Arctic water, play an important role in
the overall production patterns of the Arctic Ocean. Due to the strong water column stratification and increased light
levels involved with the melting of the ice, the location and recession of the ice edge in spring and summer determines
the timing and magnitude of the spring phytoplankton bloom, which is generally earlier than in the open water (Gradinger
and Baumann, 1991; Smith Jr. et al., 1987). Wind- or eddy-induced upwelling in the marginal ice zone, as well as
biological regeneration processes replenish the surface nutrient pool and therefore prolong the algal growth period
(Gradinger and Baumann, 1991; Smith, 1987). The hydrographic variability explains the patchy patterns of primary and
secondary production observed, as well as consequently the patchy occurrence of predators.
The polar front separates to some degree the pelagic faunas of the polar and Arctic waters in the Greenland Sea and Fram
Strait, each characterised by a few dominant copepod species with different life history strategies (Hirche et al., 1991;
see also review in Melle et al., 2005): In polar waters, Calanus glacialis uses under ice plankton production and lipid
reserves for initiating its spring reproduction phase, but depends on the phytoplankton bloom for raising its offspring (e.g.
Leu et al., 2011). Somewhat later, on the warm side of the polar front in Arctic water, the Atlantic species Calanus
finmarchicus uses the ice edge-related phytoplankton bloom for secondary production. Calanus hyperboreus, the third
and largest of the charismatic copepod species has its core area of distribution in the Arctic waters of the Greenland Sea
(Hirche, 1997; Hirche et al., 2006).
Zooplankton of the Arctic Basin
Overall zooplankton biomass decreases towards the central Arctic basin, reaching a minimum in the most northerly
waters, i.e. the region with permanent ice cover (Mumm et al., 1998). However, investigations in recent years
demonstrated increased biomasses compared to studies several decades earlier - possibly a consequence of the decrease
in ice thickness and cover which only enabled the investigations to take place from ship board.
There is a south-north decrease in zooplankton biomass, with a sharp decline north of 83°N (Hirche and Mumm, 1992),
coinciding with differences in the species composition of the biomass-forming zooplankton species. Whereas the southern
Nansen basin plankton is dominated by the Atlantic species Calanus finmarchicus, entering the Arctic Basin with the
West Spitsbergen Current, the northernmost branch of the North Atlantic current, the Arctic and polar species Calanus
hyperboreus and C. glacialis dominate the biomass in the high-Arctic Amundsen and Makarov Basins (Auel and Hagen,
2002; Mumm et al., 1998). The zooplankton species communities generally can be differentiated according to their
occurrence in Polar Surface Water (0-50 m, temperature below –1.7°C, salinity less than 33.0), Atlantic Layer (200–900
m; temperature 0.5–1.5°C); salinity 34.5–34.8) and Arctic Deep Water (deeper than 1000 m, temperature -0,5--1° C,
salinity > 34.9) (Auel and Hagen, 2002; Grainger, 1989; Kosobokova, 1982). The polar surface community in the upper
50 m of the water column consists of original polar species as well as species emerging from deeper Atlantic waters,
altogether leading to a high abundance and biomass peak in summer. Diversity and biomass are minimal in the
impoverished Arctic basin deepwater community (Kosobokova 1982). Apart from a limited exchange with the Atlantic
Ocean via the Fram Strait, the central Arctic deep-sea basins are isolated from the rest of the world ocean deepsea fauna.
Therefore, the bathypelagic fauna consists of a few endemic Arctic species and some species of Atlantic origin. Due to
the separation of the Eurasian and Canadian Basins by the Lomonosov Ridge, significant differences in hydrographic
parameters (Anderson et al. 1994) and in the zooplankton composition occur between both basins (Auel and Hagen,
2002).
Fish
Polar cod, Boreogadus saida, is a keystone species in the ice-related foodwebs of the Arctic. Due to schooling behavior
and high energy content polar cod efficiently transfer the energy from lower to higher trophic levels, such as seabirds,
seals and some whales (Crawford and Jorgenson, 1993).
Seabirds
Ice cover is a physical feature of major importance to marine birds in high latitude oceans, providing access to resources,
and refuge from aquatic predators (Hunt, 1990). As seabirds are dependent on leads between ice floes or otherwise open
water to access food, they search for the most productive waters in polynias (places within the ice which are permanently
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ICES Advice 2013, Book 1
ice free) and marginal ice zones (Hunt, 1990). Here they forage both on the pelagic and sympagic ice-related fauna,
especially the early stages of polar cod and the copepods Calanus hyperboreus and C. glacialis. Likely, they benefit from
the structural complexity and good visibility of their prey near the ice (Hunt, 1990).
In the Greenland Sea and Fram Strait, major breeding colonies exist on Svalbard, Greenland and on Jan Mayen, all of
these within reach of the seasonally moving marginal ice zone or a polynia (North East Water Polynia on the East
Greenland shelf). Breeding seabirds like Little auks (Alle alle), from colonies in the northern Svalbard archipelago feed
their offspring with prey caught in the vicinity of the nests, however intermittently travel at least 100 km to the marginal
ice zone at 80° N to replenish their body reserves (Jakubas et al., Online 03 June 2011). Therefore, the distance of the
marginal ice zone to the colony site is a critical factor determining the breeding success (e.g. Joiris and Falck, 2011).
Opportunistically, the birds also use other zooplankton aggregations such as a in a cold core eddy in the Greenland Sea,
closer to the nesting site (Joiris and Falck, 2011).
A synopsis of seabird data for the period 1974–1993 (Joiris, 2000) showed that the little auk is one of the most abundant
species, together with the fulmar Fulmarus glacialis, kittiwake Rissa tridactyla and Brünnich’s guillemot Uria lomvia in
the European Arctic seas (mainly the Norwegian and Greenland Seas). In the Greenland Sea and the Fram Strait, little
auks represented the main species in polar waters, at the ice edge and in closed pack ice, reaching more than 50% of all
bird species (Joiris and Falck, 2011). In spring and autumn, millions of seabirds pass through the area when migrating
between their breeding sites on Svalbard or the Russian Arctic and their wintering areas in Canada (Gill et al., 2011).
There are several seabird species in the European Arctic which are only met in ice-covered areas, for example the Ivory
gull Pagophila eburnea and the Thick-billed guillemot Uria lomvia (see e.g. CAFF, 2010): Both species spend the entire
year in the Arctic, and breed in close proximity to sea ice although Thick-billed guillemots were observed to fly up to 100
km from their colonies over open water to forage at the ice edge (Bradstreet 1979). The relatively rare Ivory gulls are
closely associated with pack-ice, favouring areas with 70 – 90% ice cover near the ice edge, where they feed on small
fish, including juvenile Arctic cod, squid, invertebrates, macro-zooplankton, carrion, offal and animal faeces (e.g. OSPAR
Commission, 2009b). Ivory gulls have a low reproductive rate and breeding only takes place if there is sufficient food,
which makes the population highly vulnerable to the effects of climate warming (e.g. OSPAR Commission, 2009b).
Thick-billed guillemots are relatively long lived and slow to reproduce and has a low resilience to threats including oil
pollution, by-catch in and competition with commercial fisheries operations, population declines due to hunting –
particularly in Greenland (OSPAR Commission, 2009c).
Ivory gull and Thick-billed guillemots are both listed by OSPAR as being under threat and/or decline, (OSPAR
Commission, 2008) and in 2011 recommendations for conservation action were agreed (OSPAR Commission, 2011)
which will be implemented in conjunction with the circumpolar conservation actions of CAFF (CAFF, 1996; Gilchrist et
al., 2008).
Marine mammals
Several marine mammal species permanently associate with sea ice in the European Arctic. These include polar bear,
walrus, and several seal species: bearded, Erignathus barbatus; ringed, Pusa hispida; hooded, Cystophora cristata; and
harp seal Pagophilus groenlandicus. Three whale species also occupy Arctic waters year- round – narwhal, Monodon
monoceros; beluga whale, Delphinapterus leucas; and bowhead whale, Balaena mysticetus.
Polar bears Ursus maritimus are highly specialized for and dependent on the sea ice habitat and are therefore particularly
vulnerable to changes in sea ice extent, duration and thickness. They have a circumpolar distribution limited by the
southern extent of sea ice. Three subpopulations of polar bears occur in the European high Arctic: the East Greenland,
Barents Sea and Arctic Basin sub-populations, all with an unknown population status (CAFF, 2010). Following the youngof-the-year ringed seal distribution, polar bears are most common close to land and over the shelves, however some also
occur in the permanent multi-year pack ice of the central Arctic basin (Durner et al., 2009). Due to low reproductive rates
and long lifetime, it has been predicted that the polar bears will not be able to adapt to the current fast warming of the
Arctic and become extirpated from most of their range within the next 100 years (Schliebe et al., 2008).
Walruses, Odobenus rosmarus, inhabit the Arctic ice year-round. They are conservative benthic feeders, diving to 80100 m depth for scaping off the rich mollusc fauna of the continental shelves, and need ice floes as resting and nursing
platform close to their foraging grounds. Walruses have been subject to severe hunting pressure from the end of the 18th
century to the mid-20th century, and are still hunted today in Greenland (NAMMCO). By 1934, the estimated 7000080000 individuals of the Atlantic population were reduced to 1200-1300, with none left on Svalbard (Weslawski et al.,
2000). Today’s relatively small sub-populations on the East Greenland and Svalbard-Franz Josef Land coasts have
recently shown a slightly increasing trend, in the latter case reflecting the full protection of the species since the 1950´s
(CAFF, 2010; NAMMCO). Apart from their sensitivity to direct human disturbance and pollution, it is expected that
ICES Advice 2013, Book 1
183
walruses will suffer from the changing ice conditions (location, thickness for being used as haul-out site) as well as
changes in ice-related productivity.
The Atlantic subspecies of the bearded seal, Erignathus barbatus occurs south of 85° N from the central Canadian Arctic
east to the central Eurasian Arctic, but no population estimates exist (Kovacs, 2008b). Because of their primarily benthic
feeding habits they live in ice covered waters overlying the continental shelf. They are typically found in regions of broken
free-floating pack ice; in these areas bearded seals prefer to use small and medium sized floes, where they haul out no
more than a body length from water and they use leads within shore-fast ice only if suitable pack ice is not available
(Kovacs, 2008b, and literature quoted).
The Arctic ringed seal Pusa (Phoca) hispida hispida has a very large population size and broad distribution, however,
there are concerns that future changes of Arctic sea ice will have a negative impact on the population, some of which
have already been documented in some parts of the subspecies range (Kovacs et al., 2008). As the other seals, the ringed
seal uses sea ice exclusively as their breeding, moulting and resting (haulout) habitat, and feed on small schooling fish
and invertebrates. In a co-evolution with one of their main predators, the polar bear, they developed the ability to create
and maintain breathing holes in relatively thick ice, which makes them well adapted to living in fully ice covered waters
the year round.
The West Ice (or Is Odden) to the west of Jan Mayen, at approx. 72-73° N, in early spring a stretch of more of less fast
drift ice, is of crucial importance as a whelping and moulting area for harp seals and hooded seals (summarised e.g. by
ICES, 2008). Discovered in the early 18th century, up to 350000 seals (1920s) were killed per year, decimating the
populations from an estimated one million individuals in the 1950s (Ronald et al., 1982) to today´s 70000 and 243000 of
hooded and harp seals, respectively (Kovacs, 2008a, c).
Hooded seal, Cystophora cristata, is a pack ice species, which is dependent on ice as a substrate for pupping, moulting,
and resting and as such is vulnerable to reduction in extent or timing of pack ice formation and retreat, as well as ice edge
related changes in productivity (Kovacs, 2008a, and literature quoted). Hooded Seals feed on a wide variety of fish and
invertebrates, including species that occur throughout the water column. After breeding and moulting on the West Ice
they follow the retreating pack ice to the north, but also spend significant periods of time pelagically, without hauling out
(Folkow and Blix 1999) in (Kovacs, 2008a). The northeast Atlantic breeding stock has declined by 85-90 % over the last
40-60 years. The cause of the decline is unknown, but very recent data suggests that it is on-going (30% within 8 years),
despite the protective measures that have been taken in the last few years. The species is therefore considered to be
vulnerable (Kovacs, 2008a).
Harp seals Pagophilus (Phoca) groenlandicus are the most numerous seal species in the Arctic seas. Their reproduction
takes place in huge colonies, for example on the pack ice of the ‘‘West Ice’’ north of Jan Mayen, and after the breeding
season they follow the retreating pack ice edge northwards up to 85° N, feeding mainly on polar cod under the ice (Kovacs,
2008c) .
Narwhals Monodon monoceros primarily inhabit the ice-covered waters of the European Arctic, including the ice sheet
off East Greenland (Jefferson et al., 2008b). For two months in summer, they visit the shallow fjords of East Greenland,
spending all the rest of the year offshore, in deep ice-covered waters along the continental slope in the Greenland Sea
and Arctic Basin (Heide-Jørgensen and Dietz, 1995). Narwhals are deep diving benthic feeders and forage on fish, squid,
and shrimp, especially Arctic fish species, such as Greenland halibut, Arctic cod, and polar cod at up to 1500 m depth
and mostly in winter. A recent assessment of the sensitivity of all Arctic marine mammals to climate change ranked the
narwhal as one of the three most sensitive species, primarily due to its narrow geographic distribution, specialized feeding
and habitat choice, and high site fidelity (Laidre et al. 2008 in (Jefferson et al., 2008b)).
Bowhead whales Balaena mysticetus are found only in Arctic and subarctic regions and a Svalbard-Barents population
occurs from the coast of Greenland across the Greenland Sea to the Russian Arctic. They spend all of their lives in and
near openings in the pack ice feeding on small to medium-sized zooplankton. They migrate to the high Arctic in summer,
and retreat southward in winter with the advancing ice edge (Moore and Reeves 1993 in (Reilly et al., 2008)). Whaling
has decimated the original bowhead whale populations to be rare nowadays, listed by OSPAR as being under threat and/or
decline (OSPAR Commission, 2008). The species is considered to be very sensitive to changes in the ice-related
ecosystem as well as sound disturbance, possible consequences of a progressive reduction of ice cover (OSPAR
Commission, 2009a).
Belugas Delphinapterus leucas prefer coastal and continental shelf waters with a broken-up ice cover. They have never
been surveyed around Svalbard. Pods numbering into the thousands are sighted irregularly around the archipelago, and
pods ranging from a few to a few hundred individuals are seen regularly (Gjertz and Wiig 1994; Kovacs and Lydersen
2006 in (Jefferson et al., 2008a)).
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ICES Advice 2013, Book 1
Little is known about the populations of the larger fauna in the Central Arctic Basin over the deepsea basins and ridges.
But it is not likely that it is currently an area of great abundance - too far from the coastal nesting sites of marine birds,
and over too deep water to allow feeding on benthos, as most of the larger mammals would need, and currently of too
low plankton production to feed the large whales. All of these groups have their distribution center along the continental
shelves presently - however, following the receding ice edge out to the central Arctic basin may be one of the options for
the future.
Feature condition, and future outlook
This high Arctic region is particularly vulnerable to the the loss of ice cover and other effects of the anticipated global
warming, including elevated UV radiation levels (Agustí, 2008). (Wassmann et al., 2010) summarise what changes may
be expected within the subarctic/Arctic region:
•
•
•
•
•
northward displacement (range shifts) of subarctic and temperate species, and cross-Arctic transport of
organisms;
increased abundance and reproductive output of subarctic species, decline and reduced reproductive success of
some Arctic species associated with the ice and species now preyed upon by predators whose preferred prey
have declined;
increased growth of some subarctic species and primary producers, and reduced growth and condition of animals
that are bound to, associated with, or born on the ice;
anomalous behaviour of ice-bound, ice-associated, or ice-born animals with earlier spring events and delayed
fall events;
changes in community structure due to range shifts of predators resulting in changes in the predator–prey
linkages in the trophic network.
(Wassmann, 2008) expects radical changes in the productivity, functional relationships and biodiversity of the Arctic
Ocean. He suggests that a warmer climate with less ice cover will result in greater primary production, a reduction of the
stratified water masses to the south, changes in the relationship between biological processes in the water column and the
sediments, a reduction in niches for higher trophic levels and a displacement of Arctic by boreal species. On the shelves,
increased sediment discharges are expected to lower the primary production due to higher turbidity, and enhance the
organic input to the deep ocean. A more extensive review of expected or suspected consequences of climate change for
the marine system of the Arctic is given in (Loeng et al., 2005).
Figure 3, extracted from (Gill et al., 2011), presents the conceptual ideas about possible Arctic ecosystem changes
mediated by human impact:
The normal situation shown in the upper left panel consists of ice-dependent species and species that tolerate a broader
range of temperatures and are found in waters with little or no sea ice. Primary production occurs in phytoplankton (small
dots in the figure) in ice-free waters and in ice-attached algae and phytoplankton in ice-covered waters. Phytoplankton
(small t-shaped symbols in the figure) and ice algae are the main food sources for zooplankton and benthic animals. The
fish community consists of both pelagic and demersal species. Several mammals are ice-associated, including polar bears
and several species of seals. A number of sea bird species are also primarily associated with ice-covered waters.
At moderate temperature increases (upper right) populations of ice-dependent species are expected to decline as sea ice
declines, and sub-Arctic species are expected to move northwards. Arctic benthic species are expected to decline,
especially if their distributions are pushed close to or beyond the continental slope.
The expected effects from fisheries relate to the continental shelves. Two major effects are changes in populations of
benthic organisms due to disturbance from bottom trawling and removal of large individuals in targeted fish stocks. In
addition, the size of targeted stocks, both demersal and pelagic, may be reduced.
In addition, the effects of ocean acidification are considered (lower right). Ocean acidification will result in depletion of
carbonate phases such as aragonite and calcite. This will alter the structure and function of calcareous organisms,
particularly at lower trophic levels. Changes in pH can also alter metabolic processes in a range of organisms. It is not
known how these changes will propagate to higher trophic levels, but the effects could be substantial.
Figure 3: Conceptual models showing potential impacts on Arctic marine ecosystems under different scenarios (Gill et
al., 2011).
Gill et al. (2011) conclude that the central part of the Arctic Basin is not a region for fisheries or oil and gas exploration.
However, this region has played and will continue to play a very important role in the redistribution of pollutants, due to
ice drift and/or currents between coastal and shelf areas and the Arctic Basin peripheries, far from sources of pollution.
ICES Advice 2013, Book 1
185
Assessment against CBD EBSA Criteria
Table 1
CBD
Criterion
Relation of each of the CBD criteria to the proposed area relating to the best available science. Note that a
candidate EBSA may qualify on the basis of one or more of the criteria, the boundaries of the EBSA need
not be defined with exact precision.
EBSA Description
Uniqueness or
rarity
The area contains either (i) unique (“the only one of its
kind”), rare (occurs only in few locations) or endemic
species, populations or communities, and/or (ii) unique, rare
or distinct, habitats or ecosystems; and/or (iii) unique or
unusual geomorphological or oceanographic features
Ranking of criterion relevance
(please mark one column with an X)
Don’t Know Low
Some
High
x
Explanation for ranking
Arctic sea ice, in particular the multiyear ice of the Central Arctic is globally unique and hosts endemic species such as the Gammarid
amphipod Gammarus wilkitzki and sea ice meiofauna which will disappear with the melting of the ice. Polar bears, walrusses, bowhead
whales, narwhales, belugas, several seal species and many bird species are endemic to the high Arctic ice.
While sea ice species such as G. wilkitzki are not endemic to the proposed EBSA they are endemic to the Arctic and unique within the
OSPAR area
Special importance Areas that are required for a population to survive and thrive
for life-history
stages of species
x
Explanation for ranking
Sea ice is essential for its sympagic fauna, and to some extent also for the pelagic associated fauna which also depends on the right
timing of biomass production (match/mismatch with bloom periods). The marginal ice zone and other openings in the ice are essential
feeding grounds for a large number of ice-associated species which exploit the seasonally high production there.
At present the area covered by the proposed EBSA includes both the area of permanent ice and, the area covered by seasonal ice and
the ice edge. The community associated with the ice edge requires it special structural features for a number of ecological processes,
including increased primary and secondary productivity, and feeding and resting of seabirds and marine mammals.
Area containing habitat for the survival and recovery of
x
Importance for
endangered, threatened, declining species or area with
threatened,
significant assemblages of such species
endangered or
declining species
and/or habitats
Explanation for ranking
The high arctic ice hosts endemic species such as the Gammarid amphipod Gammarus wilkitzki and sea ice meiofauna which will
disappear with the melting of the ice. Many of the obligatory ice-related species are listed as vulnerable by IUCN, and/or listed as
under threat and/or decline by OSPAR, examples include the Ivory gull, thick-billed guillemot, bowhead whale, hooded seal and polar
bear. With the overall trend of retreating sea ice extent, the proposed EBSA may become increasingly important for all ice-dependent
species in the future.
Areas that contain a relatively high proportion of sensitive
Vulnerability,
habitats, biotopes or species that are functionally fragile
fragility,
sensitivity, or slow (highly susceptible to degradation or depletion by human
activity or by natural events) or with slow recovery
recovery
186
x
ICES Advice 2013, Book 1
Explanation for ranking
The ice-related foodweb and ecosystem is highly sensitive to the ecological consequences of a warming climate. Beyond this the Arctic
is at the forefront of the impacts of ocean acidification (Wicks & Roberts 2012). The largest changes in ocean pH will occur in the
Arctic Ocean, with complete undersaturation of the Arctic Ocean water column predicted before the end of this century (Steinacher et
al. 2009). Many of the seabird and mammal populations are particularly sensitive to changes due to their already low population
numbers, and low fertility. If the retreat of the ice to the north will lead to increased shipping and oil and gas exploitation in Arctic
waters, the increased risk of spills would also pose a potential hazard for example for guillemots, which are extremely susceptible to
mortality from oil pollution (CAFF, 2010). In addition, some species like Ivory gull are sensitive to an increased heavy metal load in
their prey.
Biological
productivity
Area containing species, populations or communities with
comparatively higher natural biological productivity
Explanation for ranking
This criterion was not evaluated in the OSPAR/NEAFC/CBD Workshop. ICES did not have enough information to evaluate this
criterion.
Biological diversity Area contains comparatively higher diversity of ecosystems,
habitats, communities, or species, or has higher genetic
diversity
Explanation for ranking
This criterion was not evaluated in the OSPAR/NEAFC/CBD Workshop. ICES did not have enough information to evaluate this
criterion.
References
Aagaard, K., 1989. A synthesis of Arctic Ocean circulation. Rapport Proces et Verbeaux Réunion du Conseil international
pour l'Exploration de la Mer 188, 11-22.
Aagaard, K., Coachman, L.K., 1968. The East Greenland Current north of Denmark Strait: Part II. Arctic 21, 267-290.
Aagaard, K., Swift, J.H., Carmack, E.C., 1985. Thermohaline circulation in the Arctic mediterranean seas. Journal of
Geophysical Research 90, 4833-4846.
Agustí, S., 2008. Impacts of increasing ultraviolet radiation on the polar oceans. In: Impacts of global warming on polar
ecosystems. Duarte, C.M. (Ed.) Fundación BBVA pp. 25-46.
Anderson, L.G., Jones, E.P., Koltermann, K.P., Schlosser, P., Swift, J.H., Wallace, D.W.R., 1989. The first oceanographic
section across the Nansen Basin in the Arctic Ocean. Deep Sea Research 36, 475-482.
Angelen, J.H.v., Broeke, M.R.v.d., Kwok, R., 2011. The Greenland Sea Jet: A mechanism for wind‐driven sea ice export
through Fram Strait. Geophysical Research Letters 38 (L12805).
Anisimov, O.A., Vaughan, D.G., Callaghan, T.V., Furgal, C., Marchant, H., Prowse, T.D., Vilhjálmsson, H., Walsh, J.E.,
2007. Polar regions (Arctic and Antarctic). In: Climate Change 2007: Impacts, Adaptation and Vulnerability.
Contribution of Working Group II to the Fourth Assessment Report of the Intergovernmental Panel on Climate
Change. Parry, M.L., Canziani, O.F., Palutikof, J.P., Linden, P.J.v.d., Hanson, C.E. (Eds.)Cambridge University
Press, Cambridge pp. 653-685.
Arndt, C., E. , Pavlova, O., 2005. Origin and fate of ice fauna in the Fram Strait and Svalbard area. Marine Ecology
Progress Series 301, 55-66.
Auel, H., Hagen, W., 2002. Mesozooplankton community structure, abundance and biomass in the central Arctic Ocean.
Marine Biology 140, 1013-1021.
Bluhm, B.A., Gebruk, A.V., Gradinger, R., Hopcroft, R.R., Huettmann, F., Kosobokova, K.N., Sirenko, B.I., Weslawski,
J.M., 2011. Arctic marine biodiversity: An update of species richness and examples of biodiversity change.
Oceanography 24 (3), 232-248.
Bradstreet, M.S.M., Cross, W.E., 1982. Trophic relationships at high Arctic ice edges. Arctic 35 (1), 1-12.
CAFF, 1996. International Murre conservation strategy and action plan. CAFF International Secretariat, CAFF
Circumpolar Seabird Working Group, Akureyri, Iceland, pp. 1-16.
CAFF, 2010. Arctic Biodiversity Trends 2010. Selected indicators of change. CAFF International Secretariat, , Akureyri,
Iceland.
Carey, A.G.I., 1985. Marine Ice Fauna. In: Arctic Sea Ice Biota. A., H.R. (Ed.)CRC Press, Boca Raton. Florida pp. 17190
Crawford, R.E., Jorgenson, J.K., 1993. Schooling behaviour of arctic cod, Boreogadus saida in relation to drifting pack
ice. Environmental Biology of Fishes 36 (4), 345-357.
Durner, G.M., Douglas, D.C., Nielson, R.M., Amstrup, S.C., McDonald, T.L., Stirling, I., Mauritzen, M., Born, E.W.,
Wiig, Ø., Deweaver, E., Serreze, M.C., Belikov, S.E., Holland, M.M., Maslanik, J., Aars, J., Bailey, D.A.,
Derocher, A.E., 2009. Predicting 21st-century polar bear habitat distribution from global climate models.
Ecological Monographs 79 (1), 25-58.
ICES Advice 2013, Book 1
187
Edmonds, H.N., Michael, P.J., Baker, E.T., Connelly, D.P., Snow, J.E., Langmuir, C.H., Dick, H.J.B., Mühe, R., German,
C.R., Graham, D.W., 2003. Discovery of abundant hydrothermal venting on the ultraslow-spreading Gakkel ridge
in the Arctic Ocean. Nature 421, 252-256.
Gilchrist, G., Strøm, H., Gavrilo, M.V., Mosbech, A., 2008. International Ivory Gull conservation strategy and action
plan. CAFF International Secretariat, Circumpolar Seabird Group (CBird). CAFF Technical Report No. 18.
Gill, M.J., Crane, K., Hindrum, R., Arneberg, P., Bysveen, I., Denisenko, N.V., Gofman, V., Grant-Friedman, A.,
Gudmundsson, G., Hopcroft, R.R., Iken, K., Labansen, A., Liubina, O.S., Melnikov, I.A., Moore, S.E., Reist, J.D.,
Sirenko, B.I., Stow, J., Ugarte, F., Vongraven, D., Watkins, J., 2011. Arctic Marine Biodiversity Monitoring Plan
(CBMP-MARINE PLAN), CAFF Monitoring Series Report No.3, April 2011. CAFF International Secretariat,,
Akureyri, Iceland.
Gradinger, R., 1995. Climate change and biological oceanography of the Arctic Ocean. Phil. Trans. R. Soc. A 352, 277286.
Gradinger, R., Bluhm, B.A., 2004. In situ observations on the distribution and behavior of amphipods and Arctic cod
(Boreogadus saida) under the sea ice of the high Arctic Canadian Basin. Polar Biology 27, 595-603.
Gradinger, R., Friedrich, C., Spindler, M., 1999. Abundance, biomass and composition of the sea ice biota of the
Greenland Sea pack ice. Deep Sea Research 46, 1457-1472.
Gradinger, R., Spindler, M., Henschel, D., 1991. Development o Arctic sea-ice organisms under graded snow cover. In:
Proceedings of the Pro Mare Symposium on Polar Marine Ecology. Sakshaug, E., E., H.C.C., Øritsland, N.A.
(Eds.), Polar Research 10 (1), Trondheim pp. 295-307.
Gradinger, R.R., Baumann, M.E.M., 1991. Distribution of phytoplankton communities in relation to the large-scale
hydrographical regime in the Fram Strait. Mar. Biol. 111, 311-321.
Grainger, E.H., 1989. Vertical distribution of zooplankton in the central Arctic Ocean. In: Proc 6th Conf Comite´Arctique
Int 1985. Rey, L., Alexander, V. (Eds.) Brill Leiden pp. 48–60.
Heide-Jørgensen, M.P., Dietz, R., 1995. Some characteristics of narwhal, Monodon monoceros, diving behaviour in
Baffin Bay. Canadian Journal of Zoology 73, 2106-2119.
Hirche, H.J., 1997. Life cycle of the copepod Calanus hyperboreus in the Greenland Sea. Marine Biology 128 (4), 607618.
Hirche, H.J., Baumann, M.E.M., Kattner, G., Gradinger, R., 1991. Plankton distribution and the impact of copepod
grazing on primary production in Fram Strait, Greenland Sea. Journal of Marine Systems 2 (3-4), 477-494.
Hirche, H.J., Mumm, N., 1992. Distribution of dominant copepods in the Nansen Basin, Arctic Ocean, in summer. Deep
Sea Research Part A. Oceanographic Research Papers 39 (2, Part 1), S485-S505.
Hirche, H.J., Muyakshin, S., Klages, M., Auel, H., 2006. Aggregation of the Arctic copepod Calanus hyperboreus over
the ocean floor of the Greenland Sea. Deep Sea Research Part I: Oceanographic Research Papers 53 (2), 310-320.
Horner, R., Ackley, S.F., Dieckmann, G.S., Gulliksen, B., Hoshiai, T., Legendre, L., Melnikov, I.A., Reeburgh, W.S.,
Spindler, M., Sullivan, C.W., 1992. Ecology of sea ice biota. Habitat, terminology, and methodology. Polar
Biology 12 (3), 417-427.
Hunt, G.L.J., 1990. The pelagic distribution of marine birds in a heterogeneous environment. Polar Research 8, 43-54.
ICES, 2008. Report of the ICES Advisory Committee In: ICES Advice, Book 3, The Barents and the Norwegian SEa.
Jakubas, D., Iliszko, L., Wojczulanis-Jakubas, K., Stempniewicz, L., Online 03 June 2011. Foraging by little auks in the
distant marginal sea ice zone during the chick-rearing period. Polar Biology, 1-9.
Jefferson, T.A., Karczmarski, L., Laidre, K., O’Corry-Crowe, G., Reeves, R.R., Rojas-Bracho, L., Secchi, E.R., Slooten,
E., Smith, B.D., Wang, J.Y., Zhou, K., 2008a. Delphinapterus leucas In: IUCN 2011. IUCN Red List of
Threatened Species. Version 2011.1. www.iucnredlist.org Downloaded on 31 August 2011.
Jefferson, T.A., Karczmarski, L., Laidre, K., O’Corry-Crowe, G., Reeves, R.R., Rojas-Bracho, L., Secchi, E.R., Slooten,
E., Smith, B.D., Wang, J.Y., Zhou, K., 2008b. Monodon monoceros. In: IUCN 2011. IUCN Red List of Threatened
Species. Version 2011.1. . www.iucnredlist.org Downloaded on 31 August 2011.
Joiris, C., Falck, E., 2011. Summer at-sea distribution of little auks Alle alle and harp seals Pagophilus (Phoca)
groenlandica in the Fram Strait and the Greenland Sea: impact of small-scale hydrological events. Polar Biology
34 (4), 541-548.
Joiris, C.R., 2000. Summer at-sea distribution of seabirds and marine mammals in polar ecosystems: a comparison
between the European Arctic seas and the Weddell Sea, Antarctica. Journal of Marine Systems 27, 267-276.
Klitgaard, A.B., Tendal, O.S., 2004. Distribution and species composition of mass occurrences of large-sized sponges in
the northeast Atlantic. Progress in Oceanography 61, 57-98.
Kosobokova, K.N., 1982. Composition and distribution of the biomass of zooplankton in the central Arctic Basin.
Oceanology 22, 744-750.
Kovacs, K., 2008a. Cystophora cristata. IUCN 2011. IUCN Red List of Threatened Species. Version 2011.1.
www.iucnredlist.org Downloaded on 31 August 2011.
Kovacs, K., 2008b. Erignathus barbatus. IUCN 2011. IUCN Red List of Threatened Species. Version 2011.1.
www.iucnredlist.org Downloaded on 31 August 2011.
Kovacs, K., 2008c. Pagophilus groenlandicus. IUCN 2011. IUCN Red List of Threatened Species. Version 2011.1.
www.iucnredlist.org Downloaded on 31 August 2011.
188
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Kovacs, K., Lowry, L., Härkönen, T., 2008. Pusa hispida. In: IUCN 2011. IUCN Red List of Threatened Species. Version
2011.1. . www.iucnredlist.org Downloaded on 31 August 2011.
Kwok, R., 2009. Outflow of Arctic Ocean sea ice into the Greenland and Barents seas: 1979-2007. Journal of Climate 22,
2438-2456.
Legendre, L., Ackley, S.F., Dieckmann, G.S., Gulliksen, B., Horner, R., Hoshiai, T., Melnikov, I.A., Reeburgh, W.S.,
Spindler, M., Sullivan, C.W., 1992. Ecology of sea ice biota. Polar Biology 12 (3), 429-444.
Leu, E., Søreide, J.E., Hessen, D.O., Falk-Petersen, S., Berge, J., 2011. Consequences of changing sea ice cover for
primary and secondary producers in the European Arctic shelf seas: timing, quantity, and quality. Progress in
Oceanography 90, 18-32.
Loeng, H., Brander, K., Carmack, E.C., Denisenko, S., Drinkwater, K., Hansen, B., Kovacs, K., Livingston, P.,
McLaughlin, F., Sakshaug, E., 2005. Marine systems. In: Arctic Climate Impact Assessment, ACIA. Symon, C.,
Arrisand, L., Heal, B. (Eds.),Cambridge University Press, Cambridge pp. 453-538.
Mauritzen, C., Hansen, E., Andersson, M., Berx, B., Beszczynska-Möller, A., Burud, I., Christensen, K.H., Debernard,
J., de Steur, L., Dodd, P., Gerland, S., Godøy, Ø., Hansen, B., Hudson, S., Høydalsvik, F., Ingvaldsen, R., Isachsen,
P.E., Kasajima, Y., Koszalka, I., Kovacs, K.M., Køltzow, M., LaCasce, J., Lee, C.M., Lavergne, T., Lydersen, C.,
Nicolaus, M., Nilsen, F., Nøst, O.A., Orvik, K.A., Reigstad, M., Schyberg, H., Seuthe, L., Skagseth, Ø.,
Skar∂hamar, J., Skogseth, R., Sperrevik, A., Svensen, C., Søiland, H., Teigen, S.H., Tverberg, V., Wexels Riser,
C., 2011. Closing the loop - Approaches to monitoring the state of the Arctic Mediterranean during the
International Polar Year 2007-2008. Progress in Oceanography 90 (1-4), 62-89.
Maykut, G.A., 1985. The ice environment. In: Sea-ice biota. Horner, R. (Ed.)CRC Press, Boca Raton pp. 21-82.
Melle, W., Ellertsen, B., Skjoldal, H.R., 2005. Zooplankton: The link to higher trophic levels. In: The Nordic Seas: An
integrated perspective oceanography, climatology, biogeochemistry, and modelling. . Drange, H., Dokken, T.,
Furevik, T., Gerdes, R., Berger, W. (Eds.)Geophysical Monograph Series 158 pp. 137-202.
Mumm, N., Auel, H., Hanssen, H., Hagen, W., Richter, C., Hirche, H.J., 1998. Breaking the ice: large-scale distribution
of mesozooplankton after a decade of Arctic and transpolar cruises. Polar Biology 20 (3), 189-197.
NAMMCO, The Atlantic Walrus. North Atlantic Marine Mammal Commission. Status of Marine Mammals in the North
Atlantic, Tromsø, pp. 1-7.
OSPAR Commission, 2008. OSPAR List of Threatened and/or Declining Species andHabitats. Reference number 20086.
http://www.ospar.org/documents/dbase/decrecs/agreements/0806e_ospar%20list%20species%20and%20habitats.doc.
OSPAR Commission, 2009a. Background Document for Bowhead whale Balaena mysticetus. OSPAR Commission,
Biodiversity Series 494/2010, pp. 1-20.
OSPAR Commission, 2009b. Background Document for Ivory gull Pagophila eburnea. OSPAR Commission,
Biodiversity Series 410/2009, pp. 1-16.
OSPAR Commission, 2009c. Background Document for Thick-billed murre Uria lomvia. OSPAR Commission,
Biodiversity Series 416/2009, pp. 1-20.
OSPAR Commission, 2011. Meeting of the OSPAR Commission (OSPAR) London: 20-24 June 2011. Summary Record
OSPAR 11/20/1-E. OSPAR Commission, London.
Paquette, R., Bourke, R., Newton, J., Perdue, W., 1985. The East Greenland Polar Front in autumn. Journal of Geophysical
Research 90 (C3), 4866-4882.
Piepenburg, D., 2005. Recent research on Arctic benthos: common notions need to be revised. Polar Biology 28 (10),
733-755.
Reilly, S.B., Bannister, J.L., Best, P.B., Brown, M., , Brownell Jr., R.L., Butterworth, D.S., Clapham, P.J., Cooke, J.,
Donovan, G.P., Urbán, J., Zerbini, A.N., 2008. Balaena mysticetus. In: IUCN 2011. IUCN Red List of Threatened
Species. Version 2011.1. . www.iucnredlist.org Downloaded on 31 August 2011.
Renaud, P.E., Caroll, M.L., Ambrose, W.G.J., 2008. Effects of global warming on Arctic seafloor communities and its
consequences for higher trophic levels. In: Impacts of global warming on polar ecosystems. Duarte, C.M.
(Ed.)Fundación BBVA pp. 141-177.
Rey, F., 2004. Phytoplankton: the grass of the sea. In: The Norwegian Sea Ecosystem. Skjoldal, H.R. (Ed.)Tapir
Academic Press, Trondheim, Norway pp. 97-136.
Ronald, K., Healey, P.J., Fisher, H.D., 1982. The harp seal, Pagophilus groenlandicus. In: Small cetaceans, seals,
sirenians and otters. FAO Fisheries Series No. 5, Vol. IV, Food and Agriculture Organisation of the United
Nations. Workding Party on Mammals.
Schliebe, S., Wiig, Ø., Derocher, A.E., Lunn, N., 2008. Ursus maritimus. In: IUCN 2011. IUCN Red List of Threatened
Species. Version 2011.1. www.iucnredlist.org Downloaded on 31 August 2011.
Smith Jr, W.O., Barber, D., 2007. Polynyas and climate change: a view to the future. In: Polynays, windows to the world.
Halpern, D. (Ed.), Elsevier Oceanography Serie 74, Elsevier, Amsterdam pp. 411-420.
Smith Jr, W.O., Baumann, M.E.M., Wilson, D.L., Aletsee, L., 1987. Phytoplankton biomass and productivity in the
Marginal Ice Zone of the Fram Strait during summer 1984. Journal of Geophysical Research 92 (C7), 6777-6786.
Smith, W.O.J., 1987. Phytoplankton dynamics in the marginal ice zones. Oceanography and Marine Biology Annual
Review 25, 11-38.
ICES Advice 2013, Book 1
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Smith, W.O.J., Sakshaug, E., 1990. Polar phytoplankton. In: Polar oceanography. Part B. Chemistry, biology and
geology. Smith Jr, W.O. (Ed.) Academic Press, San Diego pp. 477-525.
Steinacher, M., Joos, F., Frölicher, T., Plattner, G. & Doney, S.c. 2009. Imminent ocean acidification in the Arctic
projected with the NcAR global coupled carbon cycle-climate model. Biogeosciences 6, 515–533.
Süfke, L., Piepenburg, D., Dorrien, C.C.v., 1998. Body size, sex ratio and diet composition of Arctogadus glacialis
(Peters, 1874) (Pisces: Gadidae) in the Northeast Water Polynya (Greenland). Polar Biology 20, 357-363.
Wadhams, P., 1981. The ice cover in the Greenland and Norwegian Seas. Rev. Geophys. Space Physics 19, 345-393.
Wassmann, P., 2008. Impacts of global warming on Arctic pelagic ecosystems and processes. In: Impacts of global
warming on polar ecosystems. Duarte, C.M. (Ed.)Fundación BBVA pp. 113-148.
Wassmann, P., 2011. Arctic marine ecosystems in an era of rapid climate change. Progress in Oceanography 90, 1-17.
Wassmann, P., Duarte, C.M., Agustí, S., Seijr, M., 2010. Footprints of climate change in the Arctic Marine Ecosystem.
Biological Global Change.
Weslawski, J.M., Hacquebord, L., Stempniewicz, L., Malinga, M., 2000. Greenland whales and walruses in the Svalbard
food web before and after exploitation. Oceanologia 42 (1), 37-56.
Wheeler, P.A., Gosselin, M., Sherr, E., Thibault, D., Kirchman, D.L., Benner, R., Whitledge, T.E., 1996. Active cycling
of organic carbon in the central Arctic Ocean. Nature 380, 697-699.
Wicks, L., Roberts, J.M. (2012) Benthic invertebrates in a high CO2 world. Oceanography & Marine Biology: An Annual
Review 50: 127 -188
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Maps and Figures
Figure 1
Location of the ecologically or biologically significant areas (EBSA) proposed by WWF in September
2011.
Figure 2
Modelled ice age distribution in 1985-2000 (left) compared to February 2008 (right) (CAFF, 2010).
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Figure 3
192
Conceptual models showing potential impacts on Arctic marine ecosystems under different
(Gill et al., 2011).
scenarios
ICES Advice 2013, Book 1
Annex 5
Note on the Sub-Polar Front
The OSPAR-NEAFC-CBD workshop report proposed an EBSA that included both the Sub-Polar Front (SPF) and the
Charlie-Gibbs Fracture Zone (CGFZ). Although that report did not describe the physical oceanographic processes causing
the linkage, it presented the information about the area in a way that implied there was a structural linkage between the
benthic-seafloor features of the CGFZ and the pelagic features of the SPF. The ICES Review Group accepted the
arguments in the earlier report for linkage between the two features. It only proposed an anchoring of the bottom of the
SPF to CGFZ, so the front moved seasonally north and south in the water column but did not sweep over the entire
seafloor between its northernmost and southernmost boundaries.
Following further study of the summary descriptions of the physical oceanography of the SPF since the ICES Review
Group discussions, the secondary sources all indicate that there is little or no structural linkage between the pelagic feature
of the SPF and the benthic feature of the CGFZ. Two illustrative quotes are given below, one from a NOAA – Univ of
Florida website on north Atlantic Oceanography, and one from the Mar-Eco website.
“It [North Atlantic Current that forms the Sub Polar front] is recognized as a shallow, widespread and variable winddriven surface movement of warm water that covers a large part of the eastern subpolar North Atlantic and slowly spills
into the Nordic Seas. It is also sometimes included as the Subarctic or Subpolar Front as it is thought of as the boundary
between the cold, subpolar region and the warm, subtropical gyre of the Northeastern Atlantic.”. (Rosensteil
Institute/NOAA)
“Near the CGFZ is also the near-surface frontal zone between cold water to the north and warm saline water to the south,
known as the Sub-polar Front.” (MarEco)
The two features have some co-incidence in two-dimensional maps of the ocean, but much less (if any) connection in
three dimensions.
Merging them as a single proposed EBSA weakens the science rationale for either feature as an EBSA. If we rank only
the benthic CGFZ against the EBSA criteria, it scores highly considering only the geo-morphology, and the limited
information available on the benthic community strengthens the case. The case for the CGFZ is considered strong enough
to stand alone and can be advanced immediately.
In relation to the pelagic SPF, there appear to be several weaknesses in the case at present. First, we do not have a clear
description of the three-dimensional structure of the SPF. Neither the description in the 2011 report (a huge rectangular
box from surface to seabed) nor the May 2013 report (a sort of trapezoid, rectangular on the surface and for some hundreds
of meters down, but then converging from both the northern summer and southern winter boundaries onto the CG fracture
zone all along the east-west centre line of the fracture) appear to match the actual structure of the SPF. If the feature has
not been described correctly, it is not possible to submit a reliable proforma about it.
In addition, a rechecking of the cited sources indicate that there is no direct evidence that, even for the first several
hundred metres of the water column (wherever the front is at a given time) actually is more productive, more diverse, or
more important to life histories of species than adjacent areas. This lack of evidence may be due to a lack of study (or a
lack of time to find such studies). ICES has found few or no analyses of satellite data on primary productivity along the
front as it moves seasonally, zooplankton productivity (possibly from analyses of CPR data), fish data from ICCAT, and
bird foraging data to determine if seabirds concentrate on the front. ICES is aware of scientists who may be able to put
together the analyses needed to better evaluate the case for the SPF, but this cannot be done within the timescale needed
for this round of the CBD process. ICES is aware of the work done to advance the case for the North Pacific Front (which
included expertise from the relevant tuna commission equivalent to ICCAT).
ICES concede that such a proforma on the SPF will miss this cycle for the CBD process, but considers that there is little
cost to that miss. The threats to the biological features of such a pelagic EBSA are fishing and shipping. Both threats
have been present for decades to centuries, and there are agencies that manage them at present. There is no knowledge
of any imminent changes to either activity that would markedly increase risks before the next CBD cycle of reporting.
Separating the pelagic SPF from the benthic CGFZ would allow both proformas to be soundly drafted. Putting the CGFZ
forward now ensures it is into the CBD process when a new and possible imminent threat of seabed mining is present,
and the case is made on its merits. It is not weakened by present issues with the information for the SPF.
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The case for the SPF can be evaluated better than it is now. It will go forward by the next cycle, and in the meantime,
existing management authorities (in particular ICCAT) can be brought more fully into process. A stronger proforma for
the SPF, with input directly from the regulatory authorities that will be most affected, mean that there is much less risk
of opposition when it does go forward.
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1.5.6.1
Special request, Advice January 2013
ECOREGION
SUBJECT
General advice
Ecological quality objective for seabird populations in OSPAR Region III
(Celtic Seas)
Advice summary
ICES collated and analysed the data for the ecological quality objective (EcoQO) indicator on breeding seabird population
trends in OSPAR Region III for the period 1986–2011. ICES considers that the proposed EcoQO indicator was not
achieved in 1986, 1989–1992, 1996 and in consecutive years during 2003–2011.
ICES advises that special attention is given to six bird species (Northern fulmar, Arctic skua, European shag, herring gull,
black-legged kittiwake, and roseate tern) that are all below the lower target levels.
ICES made two separate assessments of the EcoQO: one using both the upper and the lower target level, the other using
only the lower target level. ICES recommends excluding the upper target level of 130% when calculating the EcoQO.
ICES recommends to continue testing the application of alternative statistical methods in order to reduce the uncertainty
linked to the rather wide confidence intervals when calculating the EcoQO.
ICES advises that the target levels of the EcoQO may also be used in determining good environmental status (GES). The
lower target levels of 70% or 80% (depending on the number of eggs) can be considered as corresponding to GES for the
individual species.
Birds that are above the 130% target level and are likely to have significant negative impacts on other species may be of
concern, and ICES advises to consider these cases when assessing the GES.
Request
ICES is requested to:
i)
ii)
update the value of the draft EcoQO indicator on Seabird Population Trends in OSPAR Region III (Celtic
Seas) and make any relevant recommendations and,
consider whether or not the target thresholds [both a) the target for a species-specific trend in abundance
(e.g. 70% or more of the baseline); and b) the target for the proportion of species meeting species-specific
targets (e.g. 75% or more)] used in the EcoQO would be indicative of a seabird community that is at GES.
ICES advice
Request item i)
Update the value of the draft EcoQO indicator on Seabird Population Trends in OSPAR Region
III (Celtic Seas) and make any relevant recommendations.
Introduction
The EcoQO on seabird population trends was adopted by OSPAR’s Biodiversity Committee (BDC) in 2012 (OSPAR
Commission, 2012): Changes in breeding seabird abundance should be within target levels for 75% of species monitored
in any of the OSPAR regions or their sub‐divisions.
To date, assessments of the EcoQO have used target levels originally suggested by ICES (2008): intra-specific annual
abundance should be less than or equal to 130% of the baseline and more than or equal to 80% of the baseline, for species
that lay only one egg, or more than or equal to 70% for species that lay more than one egg. It has been debated whether
or not an upper target level should be applied when establishing the EcoQO.
To help resolve the issue, ICES made two separate assessments of the EcoQO: one uses the upper target of 130% for all
species, and another which does not use the upper target for any species.
ICES (2012) collated and analysed the most recent data for the EcoQO indicator on Seabird Population Trends in OSPAR
Region III (Celtic Seas) (Figure 1.5.5.1.1).
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Figure 1.5.5.1.1
OSPAR Region III.
Data for OSPAR Region III are collected as part of the UK and Ireland’s Seabird Monitoring Programme (SMP). The
ICES (2012) advice included data from 1986–2010 on twelve species (Northern fulmar, European shag, herring gull,
great black-backed gull, black-legged kittiwake, Sandwich tern, common guillemot, razorbill, Arctic skua, great
cormorant, little tern, and roseate tern). In this update data from 1986–2011 are included and one more species – common
tern – is added: the indicator is now based on thirteen species. Most colonies in OSPAR Region III were not surveyed in
each year of the time-series, so imputation techniques were used to estimate the missing counts. The imputation methods
and reference values used in this update are identical to those described and used in ICES (2010, 2011) and Annex 1.
Development of the EcoQO for OSPAR Region III
Using the ‘old targets’ option that includes the upper target level, the EcoQO was not achieved in 1986, 1989–1992, 1996,
and in consecutive years during 2003–2011 (see Figure 1.5.5.1.2a). Using the ‘new target option’ based only on the lower
target levels, the EcoQO was not achieved in 1986, 1989–90, 1992, and consecutively from 2005–2011 (see Figure
1.5.5.1.2b).
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a) ‘Old targets’ option
b) ‘New targets’ option
Figure 1.5.5.1.2
The proportion of species in OSPAR Region III that were within target levels of abundance during
1986–2011. The EcoQO was not achieved in years when the proportion dropped below 75%. a) The
“Old targets” option with an upper target level of 130% of the baseline and a lower target of 80/70%
of the baseline. b) The “New target” option with no upper target level.
For both options, the lower target levels were not achieved by six species in 2011, showing no change compared to the
last updates in 2009 and 2010 (ICES, 2010, 2011). The six species are: Northern fulmar, Arctic skua, European shag,
herring gull, black-legged kittiwake, and roseate tern. An overview of species with their Latin names is given in Table
1.5.5.1.1 below.
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Table 1.5.5.1.1
Species-specific assessment of relative breeding abundance in the Celtic Seas in 2011. Green cells
indicate that the species-specific targets have been met; orange cells indicate that the lower speciesspecific target has been met but that relative abundance has exceeded 130%; red cells indicate that
the lower species-specific targets have not been met. Arrows indicate recent trends in relative
abundance (2010–2011) 14. See also Figure 1.5.5.1.A1 in Annex 1.
1
Species
Fulmarus glacialis
English name
Northern fulmar
↓
2
Carbo aristotelis
European shag
↓
3
Carbo carbo
great cormorant
↓
4
Stercorarius parasiticus
Arctic skua
↓
5
Sterna sandvicencis
Sandwich tern
↓
6
Sternula albifrons
little tern
↑
7
Sterna dougalii
roseate tern
↑
8
Sterna hirundo
common tern
↓
9
Larus argentatus
herring gull
↓
10
Larus marinus
great black-backed gull
↓
11
Rissa tridactyla
black-legged kittiwake
↔
12
Uria aalge
common guillemot
↓
13
Alca torda
razorbill
↑
Roseate tern abundance has been below the lower target throughout 1986–2011, but has steadily increased during this
period from 18% to 48% of the reference level.
European shag abundance was relatively lower than roseate tern in 2011 (i.e. 29% of reference level). Shag numbers have
been at or below the lower target since 1993, but have been declining further since 2004.
Herring gull numbers have been in decline since the early 1970s, but the reference level was set at the mid-1980s level
because numbers were thought to have been previously elevated by anthropogenic activities (e.g. commercial fisheries).
Numbers have been steadily decreasing since 2000 and fell below target levels from 2003 onwards. They are currently at
53% of the reference level.
Arctic skua numbers have been below the lower target since 2005 and were at 40% of the reference level in 2011.
The decline in Northern fulmar numbers started in the mid-1990s but was steeper during 2005–2008. Their numbers
dropped below the target level in 2007, remained stable at 73% of the reference level in 2009 and 2010, but declined to
68% in 2011.
Black-legged kittiwake numbers have been declining since around 2000 and dropped just below the target level in 2008,
2010, and again in 2011.
Great black-backed gull numbers have remained within target levels throughout 1986–2011 and have shown a slight
decrease the last years. Razorbill and common guillemot numbers increased steadily during the 1980s and 1990s.
Guillemot numbers are more or less stable. Razorbill numbers peaked between 2002 and 2005 but subsequently dropped
a little and have remained within target levels since 2006.
Since 2000 the numbers of great cormorant increased but have declined since 2009, returning within target levels.
Common tern, Sandwich tern, and little tern have been increasing since late 1990s. Numbers of common tern and
Sandwich tern, though lower in 2011 compared to 2010, remain substantially above the target level. Little tern numbers
dipped dramatically between 2006 and 2010, but in 2011 numbers were once again well above the target level.
14
198
There may be a need to define how to assess the trends.
ICES Advice 2013, Book 1
ICES notes that it is useful to report on the trends in the different bird species as well. However, it is unclear how these
trends should be established and reported, e.g. over how many years etc. ICES recommends that clear guidelines for
reporting of seabird trends are developed.
Uncertainty and confidence intervals
The inherent uncertainties of the recorded (mean) trends are a cause for concern (see Figure 1.5.5.1.A1 in Annex 1).
Disregarding uncertainty when reporting the EcoQO limits the usefulness of the results. The results in terms of meeting
the target levels are interpreted mainly from the mean trends. Accordingly, the uncertainty of the trends is not assessed in
relation to the targets for species-specific trends in abundance and the target for the proportion of species meeting speciesspecific targets (e.g. 75% or more) used in the EcoQO. As an example, the lower target levels were not achieved by six
species; Northern fulmar, Arctic skua, European shag, herring gull, black-legged kittiwake, and roseate tern. By inspection
of the upper confidence levels, however, only Arctic skua and shag did not meet the species-specific target levels in 2011.
Yet, the confidence intervals are not explicitly used when making conclusions, neither on these two species nor on the
four species of seabirds for which the declines are dubious. As a result, the failure to meet the overall target of the EcoQO
in Region III is not questioned. On the other hand, when using the lower confidence intervals, also great cormorant, great
black-backed gull, and common guillemot are below the lower target. The problem with using the confidence intervals is
obvious and ICES advises not only the continued use of the mean value when assessing the EcoQO, but also to consider
improving the statistical uncertainty.
Although the Seabird Trend Wizard (see Annex I) has provided reliable confidence intervals computed by bootstrapping
the count data, the confidence intervals are rather wide for most species. Obviously, sources of variation exist in the data
which influence the uncertainty of the estimated trends. In addition, the Wizard does not smooth the count data which
makes it sub-optimal for reproducing long time-series, with alternating periods of increases and declines. Both issues may
be addressed in the further application of the EcoQO. ICES recommends to continue testing the application of alternative
statistical methods like TrendSpotter, Generalised Additive Models, and Bayesian time-series models capable of
smoothing the time-series and including co-variables, which may reduce the amount of residual ‘noise’ present in the
data.
Considerations
The failure to achieve the EcoQO in OSPAR Region III in consecutive years between 2005 and 2011 (for both target
setting options) does give rise to concern as 4–6 of the thirteen species sampled were below the lower target levels during
this period, and five species have shown substantial declines. ICES advises that special attention is given to discover the
possible causes of decline of these species and to take appropriate action.
The declines in three of these species: roseate tern, Arctic skua, and herring gull have already been highlighted within the
UK and have been listed on the UK Biodiversity Action Plan and on the Red list of Birds of Conservation Concern in the
UK. Roseate tern numbers have been increasing as a direct result of intensive management of colonies in Ireland. Arctic
skua are relatively scarce in OSPAR Region III but the trend in the region is following a steeper decline in the
neighbouring Northern Isles (OSPAR Region II) where impacts of climate and fishing on food supply have been
exacerbated by increased predation and competition from great skua. The cause of the decline in herring gulls throughout
the UK and Ireland is less well understood and ICES advises further work on this species.
The EcoQO highlights a substantial decline in shag numbers in OSPAR Region III. Declines have occurred in the rest of
the UK but not to the same extent. ICES advises further investigation into the cause of the decline.
The recent declines in kittiwake and fulmar numbers in OSPAR Region III are worth continued monitoring and further
investigation is required to determine likely causes. Kittiwake colonies within OSPAR Region III have been more
successful than colonies on the east coast of Britain (in OSPAR Region II), which have been in decline in some areas
since the late 1980s. A shortage of sandeels off the east coast is probably responsible for poor breeding there, but
kittiwakes at colonies in western Britain tend to feed on other species of fish. ICES advises more research into the variation
in availability of these prey species and the link with the decline of seabird populations.
The continued increase in guillemot numbers may be surprising when other predators of small shoaling fish (kittiwakes
and shag) have been declining and razorbill numbers have levelled off. The large increase in common terns and Sandwich
tern numbers is probably due to improved protection from predators at colonies. Despite the 2011 resurgence, the declines
in little tern numbers over the previous four years may be of concern and reasons for the decline should be investigated.
ICES debated whether or not the upper target level should be applied when establishing the EcoQO. ICES (2011)
considered applying the upper target level only to predatory species that are likely to have significant negative impacts
on other species but recommended that the EcoQO should remain unaltered, because it should be “a value-free, objective
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metric that makes no assumptions about the underlying causes of individual seabird species population change.”
However, in 2012 a group of UK experts considering UK MSFD targets recommended that the EcoQO be used without
the upper target threshold for abundance of any species. The lack of any upper threshold was considered to be more
objective than applying it only to certain species and would mean that the EcoQO would be much more straightforward.
ICES has the following considerations. In OSPAR Region III the old target level (130%) was exceeded by populations
that were previously in poor health (most tern species) or by species that were very scarce (cormorant), whereas the 130%
level should rather be a warning for possible negative interactions with other species. The terns are not considered to have
negative impacts on other species. This might be different for cormorants that compete with other species for space and
with fisheries. However, the carbo subspecies is relatively scarce with just 52 000 pairs globally, and is culled both legally
and illegally in the UK and Ireland. Also, the historical baseline will often reflect the onset of national monitoring schemes
that in many cases are established after periods of large human impact. This makes the 130% target level questionable as
a valid parameter for use in the context of EcoQO. However, birds that are above the 130% target and are likely to have
significant negative impacts on other species could be of concern. Therefore, ICES recommends that species above the
130% target are also reported.
Consequently, ICES recommends excluding the upper target threshold of 130% when calculating the EcoQO.
Further development is recommended with respect to complementary quality objectives based on parameters such as
breeding success, development of interpretation models in relation to foodwebs (information on relevant prey trends),
arranging trend data into functional groups of seabirds, and inclusion of data regarding relevant sea duck species (ICES,
2012).
Request item ii)
Consider whether or not the target thresholds [both a) the target for a species-specific trend in
abundance (e.g. 70% or more of the baseline); and b) the target for the proportion of species meeting
species-specific targets (e.g. 75% or more)] used in the EcoQO would be indicative of a seabird
community that is at GES.
ICES notes that GES is rather a national concern, whereas EcoQO targets refer to larger regions more in line with
biogeographical populations. National fluctuations in seabird abundance can be very large for some species and might be
linked to fluctuations in neighbouring countries, especially when considering numbers outside the breeding season.
Setting the right national reference levels (baseline) and selecting the right species thus seems very important when the
EcoQO is to be used as an indicative value of a seabird community in the context of GES.
When suggesting lower target levels of 70% or 80% depending on the number of eggs, ICES (2008) considered them as
values of abundance that management should be trying to maintain with high probability. This is the same rationale that
underlies target-setting to reflect the achievement of GES under MSFD. ICES advises that the lower target levels of 70%
or 80% can be considered as corresponding to GES for the individual species.
There is clearly more debate required about the inclusion of an upper target threshold for species-specific abundance for
the GES. It is questionable whether a GES only based on the lower target levels is adequate enough to establish the
environmental status. Birds that are above the 130% target and are likely to have significant negative impacts on other
species may be of concern and ICES advises to consider these when assessing the GES.
The EcoQO target threshold of 75% or more species meeting their abundance targets was recently put out to public
consultation in the UK as part of its implementation of MSFD. Several NGOs suggested raising the threshold to 90%.
Examination of Figure 1.5.5.1.2 (and applying a 90% threshold) shows that in OSPAR Region III, the EcoQO would not
have been met at all during 1986–2011 under the “old targets” option and met in just two years under the “new target”
option. Instead, the UK decided to keep the 75% threshold with the caveat that no species should be consistently missing
their individual targets, where the cause of that decline can be directly linked to human activity. ICES supports the
conclusions of the UK and recommends to keep the 75% target threshold.
Sources
ICES. 2008. Report of the Workshop on Seabird Ecological Quality Indicator (WKSEQUIN), 8–9 March 2008, Lisbon,
Portugal. ICES CM 2008/LRC:06. 60 pp.
ICES. 2010. Report of the Working Group on Seabird Ecology (WGSE), 15–19 March 2010, ICES Headquarters,
Copenhagen, Denmark. ICES CM 2010/SSGEF:10. 77 pp.
ICES 2011 Report of the Working Group on Seabird Ecology (WGSE), 1–4 November 2011, Madeira, Portugal. ICES
CM 2011/SSGEF:07. 87 pp.
ICES. 2012. Report of the Joint ICES/OSPAR Ad hoc Group on Seabird Ecology (AGSE), 28–29 November 2012,
Copenhagen, Denmark. ICES CM 2012/ACOM:82. 30 pp.
200
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Lloyd, C., Tasker, M. L., and Partridge, K. 1991. The status of seabirds in Britain and Ireland. Poyser, London.
Mitchell, P. I., Newton, S. F., Ratcliffe, N., and Dunn, T. E. 2004. Seabird Populations of Britain and Ireland. T. & A. D.
Poyser, London.
OSPAR Commission. 2012. Summary Record of the Meeting of the Biodiversity Committee (BDC) in Brest: 13–17
February 2012. OSPAR Convention for the Protection of the Marine Environment of the North-East Atlantic, BDC
12/8/1-E.
Thomas, G. E. 1993. Estimating annual total heron population counts. Applied Statistics, 42: 473-486.
Whilde, A. 1985. The All-Ireland Tern Survey 1984. Unpublished IWC/RSPB Report, Dublin.
ICES Advice 2013, Book 1
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Annex I
Methods
Since the first assessment of the EcoQO (ICES, 2008), the Joint Nature Conservation Committee (JNCC) in collaboration
with Biomathematics and Statistics Scotland developed an analytical ‘wizard’ for estimating trends in breeding numbers
of individual species at various geographical scales, including OSPAR regions. The seabird trend wizard uses a modified
chain method, first developed by Thomas (1993), to impute values of missing counts based on information in other years
and sites (details of the Thomas method are given in Annex 3 of ICES (2008)). The wizard is a small Delphi application
that retrieves counts from an Access database and generates script files and a DOS batch file that instruct R to conduct
the trend analysis using the Thomas (1993) method. A further advantage of the new wizard is that the analyses can
incorporate both whole colony counts and plot counts, even when they exist for the same colony in the same year.
The accuracy and precision of the modelled regional trend for Northern fulmar were increased by restricting data input
from only those colonies that had been surveyed for five years or more during 1986–2011. Data from all other species
contained colonies that were surveyed in two or more years during 1986–2011 (as in ICES 2008, 2010, 2011). This
reduced the sample size for fulmar to just 7% of the total number of pairs known to breed in OSPAR Region III (1998–
02 Census; Mitchell et al., 2004), compared to over 50% in all other species.
Baselines for each species were the same baselines used in ICES (2008, 2010, 2011).
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Ecological quality objectives on seabird population trends in OSPAR Region III
ICES Advice 2013, Book 1
203
Figure 1.5.5.1.A1
204
Trends in abundance of individual species in OSPAR Region III, 1986–2011. Fine dotted lines
indicate the upper and lower boot-strapped confidence limits. Bold dashed lines indicate the upper
and lower target levels; 100 = reference level (baseline). For fulmars only colonies with minimum
five years of data are used.
ICES Advice 2013, Book 1
1.5.6.2
Special request, Advice January 2013
ECOREGION
SUBJECT
General advice
Data collection and storage to implement the OSPAR seabird
recommendations
Advice summary
ICES advises that the OSPAR contracting parties share the responsibility of collating the relevant data for the seven bird
species mentioned in OSPAR’s Recommendations 2011/1–7. It is suggested that each of the individual contracting parties
(lead countries) is given the responsibility of collecting and storing data for one (or several) species.
The data collection should follow, whenever possible, international standard methods. Data for each species should be
stored by the responsible lead country as part of their national monitoring schemes. While some data are easily stored in
standard formats, others will require the development of more sophisticated formats for convenient data exchange and
comparison among contracting parties.
Standardization and harmonization of data collection methods and reporting is crucial to ensure the comparability that is
necessary for comprehensive and broader assessments at the regional and subregional levels. Several initiatives are
currently working towards international standards for collection, exchange, and storage of seabird data. ICES does not at
this stage recommend the creation of a central database, but a central portal might be considered.
ICES wishes to explore, together with OSPAR, the further development of a common format for seabird data collection
and reporting. A dedicated workshop is suggested as a possibility for relevant country experts to meet and design the
framework for the required data collection and reporting.
ICES recommends that principles similar to those stated above should apply to all OSPAR seabird data.
Request
ICES is requested to advise on suitable arrangements (including format) for data collection and storage resulting from
the implementation of OSPAR Recommendations 2011/1-7 on seabirds, taking into account existing data collection
arrangements and compatibility with current developments under MSFD implementation.
ICES advice
In 2011 OSPAR adopted seven Recommendations (OSPAR 2011/1-7) for furthering the protection and conservation of
seven bird species:
•
•
•
•
•
•
•
Lesser black-backed gull (Larus fuscus fuscus)
Ivory gull (Pagophila eburnea)
Little shearwater (Puffinus assimilis baroli)
Balearic shearwater (Puffinus mauretanicus)
Black-legged kittiwake (Rissa tridactyla tridactyla)
Roseate tern (Sterna dougallii)
Thick-billed murre (Uria lomvia)
The purpose of the Recommendations is to strengthen the protection of all life stages of these species. Article 3.2 in the
Recommendations states:
“Acting collectively within the framework of the OSPAR Commission, Contracting Parties should: develop and
implement a monitoring and assessment strategy and data collection tools to promote and coordinate the collection of
information on distribution, status of, threats to and impacts on the species, that can contribute to the implementation of
the Marine Strategy Framework Directive, where appropriate, including… “ …species-specific requirements.
1. Arrangements for data collection and storage
ICES suggests that the contracting parties share the responsibility for collating the relevant data for the seven seabird
species (according to the OSPAR Recommendations). This could be achieved by each of the individual contracting parties
(lead countries) being given the responsibility for collecting and storing data for one (or several) species.
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There is considerable variability in the available methods for collecting and reporting seabird data. This might lead to
lack of comparability, preventing comprehensive and broader assessments at the regional and subregional levels.
Consequently, standardization and harmonization of data collection and reporting (including formats) is of major
importance.
Data collection should follow international standard methods whenever possible. Walsh et al. (1995) present a
compilation of methods for survey and monitoring of seabirds. Schmeller et al. (2012) provide an overview of bird
monitoring in Europe. Both may form a useful basis for further development and agreement at the OSPAR level.
Data for each species should be stored by the responsible lead country as part of their national monitoring schemes. While
some data are easily stored in standard formats (e.g. population size, breeding success), others will require the
development of more sophisticated formats for convenient data exchange among contracting parties (e.g. tracking data,
diet data). Barrett et al. (2007) review different methods used to collect dietary data from marine birds.
Several other initiatives are currently working towards international standards for collection, exchange, and storage of
seabird data and therefore ICES does not recommend the creation of a central database at this stage. However, it is
important that data are stored in a format that allows easy comparison and exchange of data among the contracting parties.
The creation of a central portal may therefore be considered.
ICES recommends that principles similar to those stated above should apply to all OSPAR seabird data.
2.
Data collection arrangements and compatibility
In many cases, data are already being collected as part of national monitoring schemes or will be collected as part of the
implementation of the Marine Strategy Framework Directive (MSFD) or other directives, conventions, and international
agreements. Table 1.5.5.2.1 identifies known data collections and suggests a responsible contracting party for each
species; this requires further discussion by contracting parties.
Table 1.5.5.2.1
Known data collections by species. This list may not be complete.
Species
Lesser black-backed
gull
Ivory gull
Population
trends
Breeding
success
Survival
rates
Diets
X
X
X
X
Contaminants Movements
Suggested
Lead country
X
X
Norway
X
X
Norway
X
Portugal
X
Spain
X
UK
X
X
Little shearwater
X
X
Balearic shearwater
Black-legged
kittiwake
Roseate tern
X
X
X
X
X
X
X
X
X
X
X
X
UK
Thick-billed murre
X
X
X
X
X
Iceland
X
When deciding on seabird data collection and storage at the OSPAR level, some other issues must be taken into account.
Firstly, it should be determined whether the database(s) should be open to public access. For seabirds much data is
collected by interest organzations and NGOs (e.g. ESAS) in addition to data collected through state-financed projects and
monitoring programmes. Also, should access be given to data within all parameter categories? Close coordination and
comparability with other commitments must be ensured and overlapping actions avoided.
ICES is aware of funding problems related to the international collation, assessment, and reporting of seabird data. So far
ICES experts have collated and reported on data for OSPAR regions II and III, but funding for experts participating in
ICES seabird meetings is becoming increasingly scarce, a problem that should be addressed by OSPAR.
ICES recommendation
ICES wishes to explore, together with OSPAR, the further development of a common format for seabird data collection
and reporting. A dedicated workshop is suggested as a possibility for relevant country experts to meet and design the
framework for the required data collection and reporting.
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Sources
Barrett, R. T., Camphuysen, K., Anker-Nilssen, T., Chardine, J. W., Furness, R. W., Garthe, S., Hüppop, O., Leopold, M.
F., Montevecchi, W. A., and Veit, R. R. 2007. Diet studies of seabirds: a review and recommendations. ICES
Journal of Marine Science, 64: 1675–1691.
ICES. 2011. Report of the Working Group on Seabird Ecology (WGSE), 1–4 November, Madeira, Portugal. ICES CM
2011/SSGEF:07.87 pp.
ICES. 2012. Report of the Joint ICES/OSPAR Ad hoc Group on Seabird Ecology (AGSE), 28–29 November 2012,
Copenhagen, Denmark. ICES CM 2012/ACOM:82. 30 pp.
Schmeller, D. S., Henle, K., Loyau, A., Besnard, A., and Henry, P-Y. 2012. Bird-monitoring in Europe – a first overview
of
practices,
motivations
and
aims.
Nature
Conservation,
2:
41–57.
(www.pensoft.net/journals/natureconservation/article/3644)
Walsh, P. M., Halley, D. J., Harris, M. P., del Nevo, A., Sim, I. M. W., and Tasker, M. L. 1995. Seabird monitoring
handbook for Britain and Ireland. JNCC/RSPB/ITE/Seabird Group, Peterborough, UK.
ICES Advice 2013, Book 1
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1.5.6.3
Special request, Advice June 2013
ECOREGION
General advice
SUBJECT
OSPAR special request on review of the technical specification and
application of common indicators under D1, D2, D4, and D6
Advice summary
ICES undertook a simulation benchmarking exercise on the 35 common indicators whose technical specifications had
been supplied by OSPAR. ICES advises that 17 of the indicators in the Greater North Sea can be considered highperforming; 14 are close to being fully operational and 19 are adequately monitored throughout the North Sea.
ICES did not assess the performance of the indicators in regions other than the Greater North Sea, but considers that
analysis of this region will help in the understanding and further development of indicators in other regions.
ICES cannot define the precise nature of good environmental status (GES) as this is an EU Member State issue, but
advises that in order to better understand GES, it would be helpful to develop further indicators, so that a more holistic
ecosystem view can be achieved and potential additional monitoring needs can be identified.
A technical review of the two OSPAR common indicators on non-indigenous species is provided.
Request
ICES is requested to undertake an independent peer review of the technical specifications and proposed operational
implementation of the indicators (COBAM draft indicators) presented. The review should consider, from the perspective
of producing a set of common indicators for the OSPAR Region:
1.
2.
3.
4.
whether the indicators put forwards are appropriate to implement at a regional scale;
whether the set of indicators is sufficient as a set to understand GES;
identify any gaps;
identify where there are difficulties in the operationalization of the indicators, with proposals for how to
overcome these.
Based on the outcomes of Request regarding maximising efficiencies for monitoring of biodiversity:
5. identify where there are opportunities to cluster indicators that can benefit from shared monitoring/ data
collection.
(OSPAR request 3/2013)
ICES has addressed consideration 5 in its response to the request on maximizing the use of available sources of data for
monitoring of biodiversity (ICES Advice 2013, Section 1.5.5.2).
ICES advice
Overall review
Based on 16 criteria, 35 indicators were reviewed based on the information available in the Technical Specifications
provided by OSPAR ICG–COBAM (for four indicators no technical specifications were made available). The criteria
approach used here can help to guide future selection for currently underdeveloped indicators, providing a method for
selecting one indicator over the other. The results of the assessment for the Greater North Sea are summarized below for
three ecosystem aspects of the indicators.
Overall performance
A simulation benchmarking exercise was conducted on the 35 common indicators whose technical specifications had
been supplied by OSPAR. Based on the scoring of the criteria and the thresholds set for the analysis ICES found that 17
of the indicators in the Greater North Sea can be considered high-performing; 14 are close to being fully operational, and
19 are adequately monitored throughout the North Sea. The interpretation of the indicator scores depends largely on the
benchmarking procedure used and the resulting thresholds. The outcome of the assessment is affected by both the
knowledge of the performance of the indicator and by the level of detail provided in the technical specifications.
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Operational implementation
To improve the 21 indicators that are identified as less operational, in particular those that are currently categorized as
core indicators, ICES recommends focussing further work on (1) integrating surveys and improving the current cost
effectiveness of data collection (see reply to OSPAR request 4/2013 in ICES Advice 2013, Section 1.5.5.2) and (2)
extending the spatial scale of the existing monitoring. Benthic and pelagic habitat indicators will need improvement in
terms of monitoring and ability to understand how the metric can vary, whereas for species indicators, particularly for
birds and mammals, improvements should be directed towards the spatial extent of monitoring. The results of the
evaluation presented here only apply to the Greater North Sea (OSPAR Region II).
Regional coverage
ICES was unsure as to the meaning of “appropriate to implement at a regional scale” as this could mean at an subregional scale, or it might imply ‘appropriate for all OSPAR regions’. An analytical evaluation exercise was undertaken
to assess the adequacy of current monitoring (as described in the technical specifications) for the Greater North Sea.
Seventeen indicators have inadequate geographical monitoring within the North Sea (i.e. monitoring is undertaken across
a limited fraction of the sub-region). Considering the Greater North Sea as a relatively data-rich region, the results are
likely to be lower in other OSPAR regions. For many indicators, however, information on relevant monitoring
programmes was limited in the technical specifications and this may have biased the results presented here.
Understanding GES and gap analysis
Identification of the critical ecosystem components and the most effective indicators to monitor these is essential to
understand GES. Three of these ecosystem aspects were reviewed by ICES: 1) whether there are gaps in the list of OSPAR
indicators compared to the indicators defined by the European Commission (Decision 2010/477/EU); 2) whether there
are gaps in the list of indicators for important parts of the marine ecosystem; and finally 3) whether any of the present
indicators are redundant.
Gaps in OSPAR’s list of common indicators related to MSFD
The 35 OSPAR common indicators do not address fully the Marine Strategy Framework Directive (MSFD) indicators
listed in the EU Decision (2010/477/EU). ICES notes that it is not essential for all ecosystem aspects to be covered by
OSPAR common indicators, as further indicators may be implemented individually by EU Member States to help in
defining GES.
•
•
•
•
•
•
•
Within the three species-level ecosystem components (birds, mammals, and fish), no OSPAR common indicator
addresses the requirement for indicators of ‘population genetic structure’ (MSFD indicator 1.3.2).
No seabird or mammal OSPAR common indicator addresses the requirement for indicators of ‘composition and
relative proportions of ecosystem components’ (MSFD indicator 1.7.1).
None of the OSPAR common indicators addressing foodweb (MSFD indicators 4.1.1 and 4.3.1) use benthic
invertebrate metrics.
MSFD indicator 1.1.3 applies specifically to benthic species and habitats, yet none of the OSPAR common
indicators address the requirements for this indicator.
No OSPAR common indicator for fish and cephalopods is linked to the distribution range and distribution pattern
(MSFD indicators 1.1.1 and 1.1.2), or to the population demographics (MSFD indicator 1.3.1). ICES notes that
two distribution indicators (FC-7 and FC-8) and a proportion of mature fish (FC-6) indicator were listed in part
B of ICG–COBAM’s report as potential candidate indicators, but no details were provided in the technical
specifications.
None of the benthic habitat OSPAR common indicators addressed the habitat-level MSFD indicator
requirements for distributional range (1.4.1), distributional pattern (1.4.2), or volume (1.5.2).
None of the OSPAR common indicators address the impact of non-indigenous species (MSFD indicators 2.2.1
and 2.2.2).
In addition ICES found four major issues relevant to poor linkages between MSFD Decision indicators and OSPAR
common indicators as specified in the ICG–COBAM document (Table 1.5.5.1.1).
ICES Advice 2013, Book 1
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Table 1.5.5.1.1
Problems with linkages between MSFD Decision indicators and OSPAR common indicators as specified in the
ICG–COBAM document. The issues (left hand column) are: (1) The OSPAR common indicator does not seem
to relate to the MSFD indicator; (2) This multimetric indicator does not fit the definition of the MSFD indicator,
but is implicitly part of it; (3) This OSPAR indicator is considered relevant by OSPAR, but is not a MSFD
indicator specified in the Decision document; (4) This linkage is tenuous, with insufficient detail provided in
the ICG–COBAM Technical Specifications document to be convincing.
No. of issue
MSFD Decision indicator
OSPAR ICG–COBAM indicator
1
1.2.1 (Population abundance and/or biomass)
1
1.3.1 (Population demographic characteristics)
1
1.3.1 (Population demographic characteristics)
1
1.3.1 (Population demographic characteristics)
1
1.6.1 (Condition of the typical species and
communities)
1.6.2 (Relative abundance and/or biomass)
FC-4 (Bycatch rates of
Chondrichthyes)
M-6 (Proportion of bycaught
individuals within a species
population)
B-4 (Non-native/invasive mammal
presence in island seabird colonies)
B-5 (Mortality of marine birds from
fishing (bycatch) and aquaculture)
FC-3 (Mean maximum length of
demersal fish and elasmobranchs)
FC-2 (OSPAR EcoQO for proportion
of large fish (LFI))
BH-2 (Multi-metric indices)
1
2
2
2
3
4
4
1.6.1 (Condition of the typical species and
communities)
1.6.2 (Relative abundance and/or biomass)
6.2.1 (Presence of particularly sensitive and/or tolerant
species)
4.3.1 (Abundance trends of functionally important
selected groups/species)
6.2.2 (Multi-metric indices assessing benthic
community condition and functionality)
6.2.2 (Multi-metric indices assessing benthic
community condition and functionality)
BH-2 (Multi-metric indices)
BH-2 (Multi-metric indices)
FW-9 (Ecological network analysis
indicator (e.g. trophic efficiency, flow
diversity)
PH-1 (Changes in plankton functional
types (life form) index ratio)
FW-5 (Change in plankton functional
types (life form) index ratio between:
gelatinous zooplankton and fish
larvae; copepods and phytoplankton;
holoplankton and meroplankton
Ecological gaps
The proposed OSPAR common indicators reflect the seven OSPAR ecosystem components (seabirds, marine mammals
and reptiles, fish and cephalopods, benthic and pelagic habitats, foodwebs, and non-indigenous species). However, focus
on such broad groups may mean that other ecosystem components are ignored, and some of these may indeed have a
bearing on determining whether GES at the whole ecosystem level has actually been achieved in any given OSPAR
region. ICES therefore listed potential ecological gaps (Table 1.5.5.1.2), which may aid the further development of new
indicators and identify potential additional monitoring needs.
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Table 1.5.5.1.2
Gaps in the OSPAR common indicators that may need to be filled to fully define GES.
OSPAR ecosystem
component
Rocky and mixed
benthic habitats
Deep-water habitats
and species
Microplankton and
microbenthos
Cephalopods
Coastal and inshore
fish communities
Highly migratory fish
and reptiles
Non-indigenous
species
Identified gaps
There is little sampling of rocky and mixed benthic habitats for the status assessment of
benthic fauna and fish species, partly due to the risk of sustaining damage to the trawl. Rocky
habitats often host sensitive species and may provide refuge from fishing.
The majority of surveys operate in coastal shelf seas and not in deeper waters, including those
within the North Sea, Skagerrak, and Kattegat.
For PH-1 and FW-5 (Table 1.5.5.1.1), OSPAR identified micro-, pico-, nano-phytoplankton
and bacteria and micro-zooplankton including ciliates as being undersampled. These groups
are essential components of the microbial loop of marine food webs but ICES notes that
substantial effort would be required to obtain reasonably precise estimates given the
extremepatchiness of such organisms in space and time.
Cephalopods are caught in fisheries research surveys (e.g. IBTS) and hence data for the
assessment of status of at least some species under FC-1, FC-7, and FC-8 (Table 1.5.5.1.1)
should be available.
Coastal fish communities are not required to be monitored under the Water Framework
Directive. Existing surveys do not sample in shallower coastal zone waters. Shallow coastal
waters are important during the juvenile phase of the life-history of many fish species.
Sharks, tunas, and other highly migratory fish are only partly addressed by the OSPAR
common indicators and none consider the status of reptiles.
The importance of different pathways and associated vectors for each country should be
assessed, after which a final decision on common indicators should be made. In addition to
invasion vectors and pathways, the monitoring strategy should also depend on the taxa to be
sampled. Impacts caused by non-indigenous species should be assessed.
Redundant indicators
In some cases, correlations between the health of different ecosystem components and/or indicators could be used to
reduce the number of indicators needed. Potential correlation between indicators should be recognised in order to avoid
misleading impressions of actual progress towards GES. ICES suggests a criterion “Indicators making up a suite of
indicators should reflect variation in different attributes of the ecosystem component and thus be complementary” to
identify situations where indicator redundancy could be an issue. Since the indicators are at varying stages of development
and/or the information necessary to assess each OSPAR common indicator against this criterion was not provided in the
ICG–COBAM Technical Specifications document, ICES was not able to assess whether any of the currently listed
indicators contain elements of redundancy.
Background
ICES evaluated each indicator (based on the technical specifications supplied by OSPAR) using a standardized framework
(ICES, 2013a). It is important to note the distinction between the indicator and its technical specification, as a poor
specification could devalue a good indicator. ICES could only work with the specifications that had been provided and
could not make assumptions about what was not in the specification.
Table 1.5.5.1.3 lists the criteria used to evaluate the performance of OSPAR’s proposed common indicators and provides
the importance weightings assigned to each criterion, their associated scores, and the guidelines for assessing the
compliance of each indicator against each criterion. These criteria were essentially devised to assess the performance of
‘state’ indicators. However, the OSPAR common indicators also include ‘pressure’ indicators. It is inappropriate to
evaluate such indicators against criteria for assessing the state indicators to variation in pressure. A pressure indicator
should be, by definition, extremely sensitive and responsive to variation in the ecological pressure it purports to measure.
Each indicator was therefore first assessed against criterion 1, which distinguished state indicators from pressure
indicators. If the indicator was considered to be a pressure indicator, then it was automatically given a compliance score
of zero against criteria 6, 8, 12, and 13 (highlighted in Table 1.5.5.1.3), as these are relevant only to state indicators.
The importance weightings assigned to each criterion were given scores of Essential = 3, Desirable = 2, and Informative
= 1, and the compliance fits were assigned scores of Fully met = 1, Partially met = 0.5, and Not met = 0. Multiplying
these two values together provided a score for the performance of each indicator against each criterion. Summing these
scores across all criteria then generated an overall score for the general performance of the indicator against all the criteria.
The decision to give pressure indicators a compliance score of 0 introduces a bias in the assessment process in favour of
state indicators. ICES notes the need for both “state” and “pressure” indicators so that the “pressure–state” relationship
ICES Advice 2013, Book 1
211
can be adequately defined, and pressure indicators are essential in providing the scientific basis for advice regarding the
most appropriate management measures required to achieve GES. Pressure indicators are also required for Descriptor 6.
Criterion 16 considers correlations between indicators and was not used in the evaluation of the performance of the
OSPAR common indicators. This criterion is intended to select metrics that measure different attributes of an ecosystem
component’s condition, and to discourage selection of metrics that essentially perform similar functions. Therefore, this
criterion should be applied after the main assessment process, to aid further selection between high performing indicators.
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Table 1.5.5.1.3
Criterion
No.
Criteria used to evaluate the performance of common indicators proposed by OSPAR to support implementation of the MSFD at the sub-regional and
regional scales. The 16 criteria are grouped into five main categories, and the principle characteristic of each indicator’s performance examined by each
criterion is given. The importance weightings, and their associated scores, are shown, as are the guidelines for assessing the level of compliance of each
indicator against each criterion. Pale blue cells indicate criteria that were not used in the evaluation. In the compliance guidelines column, criteria are
given a zero compliance score if the indicator relates to a ‘pressure’ (Criterion 1).
Category
Characteristic
Criterion
Type of
Indicator
State or pressure Is a “pressure” indicator being used for want of an
appropriate “state” indicator?
Importance
Weighting
Importance
Score A
1
Quality of
underlying
data
Existing and
ongoing data
Indicators must be supported by current or planned
monitoring programmes that provide the data
necessary to derive the indicator. Ideal monitoring
programmes should have a time series capable of
supporting baselines and reference point setting.
Data should be collected on multiple sequential
occasions using consistent protocols, which
account for spatial and temporal heterogeneity.
Indicators should Indicators should ideally be easily and accurately
be concrete
determined using technically feasible and quality
assured methods, and have a high signal-to-noise
ratio.
Essential
3
Essential
3
Quantitative
Quantitative measurements are preferred over
versus qualitative qualitative, categorical measurements, which in
turn are preferred over expert opinions and
professional judgments.
Relevant spatial Data should be derived from a large proportion of
coverage
the MSFD sub-region, at appropriate spatial
resolution and sampling design, to which the
indicator will apply.
Desirable
2
Essential
3
2
Quality of
underlying
data
3
4
Quality of
underlying
data
Quality of
underlying
data
5
ICES Advice 2013, Book 1
Guidelines for Compliance Assessment
Score B
Fully met (1): indicator is a “state” indicator. Not met (0):
indicator is actually a “pressure” indicator. Although
scoring 0 in this criterion, and linked criterion further on in
this table, ICES recognises that pressure indicators are
essential in management decision making and in indicators
for D6.
Fully met (1): long-term and ongoing data from which
historical reference levels can be derived and past and future
trends determined. Partially met (0.5): no baseline
information, ongoing monitoring or historical data available,
but monitoring programme discontinued; however, potential
to re-establish the programme exists. Not met (0): data
sources are fragmented, no planned monitoring programme
in the future.
Fully met (1): data and methods are technically feasible,
widely adopted, and quality assured in all aspects, signal-tonoise ration is high. Partially met (0.5): potential issues with
quality assurance, or methods not widely adopted, poor
signal-to-noise ratio. Not met (0): indicator is not concrete or
doubtful; noise excessively high due either to poor data
quality or the indicator is unduly sensitive to environmental
drivers.
Fully met (1): all data for the indicator are quantitative.
Partially met (0.5): data for the indicator are semiquantitative or largely qualitative. Not met (0): the indicator
is largely based on expert judgement.
Fully met (1): spatially extensive monitoring is undertaken
across the sub-region. Partially met (0.5): monitoring does
not cover the full sub-region, but is considered adequate to
assess status at the sub-regional scale. Not met (0):
monitoring is undertaken across a limited fraction of the
sub-region and considered inadequate to assess status at the
sub-regional scale.
213
Criterion
No.
Category
Characteristic
Criterion
Importance
Weighting
Importance
Score A
Guidelines for Compliance Assessment
Score B
Quality of
underlying
data
Reflects changes
in ecosystem
component that
are caused by
variation in any
specified
manageable
pressures
The indicator reflects change in the state of an
ecological component, caused by specific
significant manageable pressures (e.g. fishing
mortality, habitat destruction). The indicator
should therefore respond sensitively to particular
changes in pressure. The response should be
unambiguous and in a predictable direction, based
on theoretical or empirical knowledge, thus
reflecting the effect of change in pressure on the
ecosystem component in question. Ideally the
pressure–state relationship should be defined under
both the disturbance and recovery phases.
Essential
3
Management
Relevant to
MSFD
management
targets
Relevant to
management
measures
Clear targets that meet appropriate target criteria
(absolute values or trend directions) for the
indicator can be specified that reflect management
objectives, such as achieving GES.
Indicator links directly to management response.
The relationship between human activity and
resulting pressure on the ecological component is
clearly understood.
Desirable
2
Desirable
2
Comprehensible Indicators should be interpretable in a way that is
easily understandable by policy-makers and other
non-scientists (e.g. stakeholders) alike, and the
consequences of variation in the indicator should
be easy to communicate.
Desirable
2
IF CRITERION 1 IS SCORED 0 THEN THE
COMPLIANCE SCORE B MUST BE 0. Otherwise: Fully
met (1): the indicator is primarily responsive to a single or
multiple pressures and all the pressure–state 15 relationships
are fully understood and defined, both under the disturbance
and recovery phases of the relationship. Partially met (0.5):
the indicator’s response to one or more pressures are
understood, but the indicator is also likely to be significantly
influenced by other non-anthropogenic (e.g. environmental)
drivers, and perhaps additional pressures, in a way that is not
clearly defined. Response under recovery conditions may
not be well understood. Not met (0): no clear pressure–state
relationship is evident.
Fully met (1): an absolute target value for the indicator is
set. Partially met (0.5): no absolute target is set for the
indicator, but a target trend direction for the indicator is
established. Not met (0): targets or trends unknown.
IF CRITERION 1 IS SCORED 0 THEN THE
COMPLIANCE SCORE B MUST BE 0. Otherwise: Fully
met (1): both response-activity and activity–pressure
relationships 16 are well defined – advice can be provided on
both the direction AND the extent of any change in human
activity required, and the precise management measures
required to achieve this. Partially met (0.5): response–
activity and activity–pressure relationships are not well
understood, or only one of the relationships is defined, but
not the other, so that the precise changes in pressure
resulting from particular management actions cannot be
predicted with certainty. Not met (0): no clear understanding
of either relationship, so that the link between management
response and pressure is completely obscure.
Fully met (1): the indicator is easy to understand and
communicate. Partially met (0.5): a more complex and
difficult to understand indicator, but one for which the
meaning of change in the indicator value is easy to
6
7
Management
8
Management
9
15
The term “pressure–state relationship” is used here in the sense described by Piet et al. (2007): e.g. fishing pressure (fishing mortality rate [F]) – state of the stock (stock biomass [B]).
16
Here the terms response–activity relationship and activity–pressure relationship are used in the sense described by Piet et al. (2007); e.g. management response (total allowable catch) – fishing activity (daysat-sea), and fishing activity (days-at-sea) – fishing pressure (fishing mortality rate [F]).
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Criterion
No.
Category
Characteristic
Criterion
Importance
Weighting
Importance
Score A
Guidelines for Compliance Assessment
Score B
communicate. Not met (0): the indicator is neither easy to
understand nor communicable.
Management
Established
indicator
Management
Costeffectiveness
Management
Early warning
Conceptual
Scientific
credibility
10
11
12
13
Conceptual
14
15
Conceptual
Indicator
suites
16
Indicators used in established management
frameworks (e.g. EcoQO indicators) are preferred
over novel indicators that perform the same role.
Internationally used indicators should have
preference over indicators used only at a national
level.
Sampling, measuring, processing, analysing
indicator data, and reporting assessment outcomes,
should make effective use of limited financial
resources.
Indicators that signal potential future change in an
ecosystem attribute before actual harm is indicated
are advantageous. These could facilitate preventive
management, which could be less costly than
restorative management.
Scientific, peer-reviewed findings should underpin
the assertion that the indicator provides a true
representation of variation in the ecosystem
attribute in question.
Metrics relevance For descriptors D1 and D6, metrics should fit the
to MSFD
indicator function stated in the 2010 MSFD
indicator
Decision document. This requirement can be
relaxed for D4 indicators because the Decision
document stipulates the need for indicator
development in respect of this Descriptor (but any
newly proposed D4 indicators must still fulfil the
overall goals stated for D4).
Cross-application Metrics that are applicable to more than one MSFD
indicator are preferable.
Indicator
Different indicators making up a suite of indicators
correlation
should each reflect variation in different attributes
of the ecosystem component and thus be
complementary. Potential correlation between
indicators should be avoided.
ICES Advice 2013, Book 1
Desirable
2
Fully met (1): the indicator is established and used in
international policy frameworks. Partially met (0.5): the
indicator is established as a national indicator. Not met (0):
the indicator has not previously been used in a management
framework.
Desirable
2
Informative
1
Desirable
2
Essential
3
Fully met (1): little additional costs (no additional sampling
is needed). Partially met (0.5): new sampling on already
existing programmes is required. Not met (0): new sampling
on new monitoring programmes are necessary.
IF CRITERION 1 IS SCORED 0 THEN THE
COMPLIANCE SCORE B MUST BE 0. Otherwise: Fully
met (1): indicator provides early warning because of its high
sensitivity to a pressure or environmental driver with short
response time; Not met (0): relatively insensitive indicator
that is slow to respond.
IF CRITERION 1 IS SCORED 0 THEN THE
COMPLIANCE SCORE B MUST BE 0. Otherwise: Fully
met (1): peer-reviewed literature. Partially met (0.5):
documented, but not peer-reviewed. Not met (0): not
documented, or peer-reviewed literature is contradictory.
Fully met (1): the metric complies with indicator function.
Not met (0): the metric does not comply with indicator
function.
Desirable
2
Desirable
2
Fully met (1): metric is applicable across several MSFD
indicators. Not met (0): no cross-application.
Fully met (1): the indicators are uncorrelated. Partially met
(0.5): correlation between some indicators. Not met (0): all
indicators are correlated.
215
The analytical evaluation exercise was undertaken only for the Greater North Sea due to there being insufficient data and
expertise on the other MSFD-relevant OSPAR sub-regions present at the relevant ICES expert group meetings. ICES
considers that the process could be readily applied to the remaining OSPAR sub-regions. Evaluation of each of the
OSPAR common indicators against criteria 2 to 15 was undertaken independently by at least three separate experts and
the mean overall assessment scores, along with the range of overall scores, was determined (Figure 1.5.5.1.1). 17
Figure 1.5.5.1.1
Mean and range of three independent evaluations (four in the case of the foodweb (FW) indicators)
of the performance of 35 OSPAR common indicators against criteria 2 to 15 listed in Table 1.5.5.1.3.
Pressure (P) indicators were automatically assigned a zero compliance score against four criteria
deemed not applicable to pressure indicators (see text and Table 1.5.5.1.3). For abbreviation of
indicators see Table 1.5.5.1.4.
The OSPAR common indicators are intended to enhance cooperation between Member States sharing marine regions so
that status assessment can be made across whole MSFD sub-regions and regions. The mean scores given to each OSPAR
common indicator against criterion 5 (relevant spatial coverage) was therefore determined to identify the most useful
OSPAR common indicators in this respect (Figure 1.5.5.1.2). ICES assessed the degree to which each of the proposed
OSPAR common indicators could be readily used, based on each indicator’s performance against criteria 2, 3, 4, 5, 10,
and 11. The mean score given to each OSPAR common indicator against these criteria was determined (Figure 1.5.5.1.3).
17
It should be noted that ICES assessed the performance of 35 OSPAR common indicators. ICES is aware that several more common
indicators are under consideration, but the version of the document “Report by ICG–COBAM on the development of an OSPAR common
set of biodiversity indicators: Part C: Technical Specifications” available to expert groups only provided details for 35 indicators.
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ICES Advice 2013, Book 1
Table 1.5.5.1.4
Abbreviations and categories of the 35 proposed biodiversity OSPAR common indicators as
described in the ICG–COBAM Part C: Technical Specifications document.
Code
Indicator
Mammals
M-1
Distributional range and pattern of grey and harbour seal haul-out sites and breeding colonies
M-2
Distributional range and pattern of cetaceans species regularly present
M-3
Abundance of grey and harbour seal at haul-out sites
M-4
Abundance at the relevant temporal scale of cetacean species regularly present
M-5
Harbour seal and Grey seal pup production
M-6
Numbers of individuals within species being bycaught in relation to population
Marine birds
Species-specific trends in relative abundance of non-breeding and breeding marine bird
B-1
species
B-2
Annual breeding success of kittiwake
B-3
Breeding success/failure of marine birds
B-4
Non-native/invasive mammal presence on island seabird colonies
B-5
Mortality of marine birds from fishing (bycatch) and aquaculture
B-6
Distributional pattern of breeding and non-breeding marine birds
Fish and cephalopods
FC-1
Population abundance/ biomass of a suite of selected species
FC-2
OSPAR EcoQO for proportion of large fish (LFI)
FC-3
Mean maximum length of demersal fish and elasmobranchs
FC-4
Bycatch rates of Chondrichthyes
Benthic habitat
BH-1
Typical species composition
BH-2
Multi-metric indices
BH-3
Physical damage of predominant and special habitats
BH-4
Area of habitat loss
BH-5
Size–frequency distribution of bivalve or other sensitive/indicator species
Pelagic habitat
PH-1
Changes of plankton functional types (life form) index ratio
PH-2
Plankton biomass and/or abundance
PH-3
Changes in biodiversity index (s)
Food webs
FW-1
Reproductive success of marine birds in relation to food availability
FW-2
Production of phytoplankton
FW-3
Size composition in fish communities (LFI)
FW-4
Changes in average trophic level of marine predators
FW-5
Change of plankton functional types (life form) index ratio
FW-6
Biomass, species composition, and spatial distribution of zooplankton
FW-7
Fish biomass and abundance of dietary functional groups
FW-8
Changes in average faunal biomass per trophic level
FW-9
Ecological network analysis indicator (e.g. trophic efficiency, flow diversity)
Non-indigenous species
NIS-1
Pathways management measures
NIS-2
Rate of new introductions of NIS (per defined period)
ICES Advice 2013, Book 1
Category
Core
Core
Core
Core
Core
Core
Core
Core
Core
Candidate
Core
Core
Core
Core
Candidate
Core
Core
Candidate
Candidate
Candidate
Core
Core
Core
Core
Core
Core
Core
Core
Candidate
Candidate
Candidate
Candidate
Candidate
Candidate
217
Figure 1.5.5.1.2
Spatial coverage. Evaluation of the performance of 35 OSPAR common indicators (abbreviations in Table
1.5.5.1.4) against criterion 5 (relevant spatial coverage) listed in Table 1.5.5.1.3. Indicators B-4 and B-5
received zero scores. P indicates a “pressure” indicator.
Figure 1.5.5.1.3
Useability. Evaluation of the performance of 35 OSPAR common indicators (abbreviations in Table 1.5.5.1.4)
against criteria 2, 3, 4, 5, 10, and 11 (related to the ability to use the indicators immediately) listed in Table
1.5.5.1.3. P indicates a “pressure” indicator.
Comparing between categories of indicators
The process undertaken by ICES means that it is not possible to directly compare pressure and state indicators, nor their
readiness for immediate use. It would be possible for experts to chose thresholds, but these would be partly arbitrary and
would reflect the opinions (and possible biases) of experts involved in any given indicator assessment exercise; different
groups of experts might therefore set different benchmark threshold scores, thus generally compromising the repeatability
and consistency of such objective indicator assessment exercises. A simulation exercise was therefore undertaken (ICES,
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ICES Advice 2013, Book 1
2013b) in order to understand the significance of scores in each of these categories (Figure 1.5.5.1.4, Table 1.5.5.1.5).
ICES has based the advice on the performance of indicators on the thresholds that derive from this process.
In Figure 1.5.5.1.4 is shown the simulated distribution of scores that will likely be generated when a very large set of
virtual “state” and “pressure” indicators are put through the scoring system. Figure 1.5.5.1.4 indicates the mean score and
the upper 25-percentile, upper 10-percentile, and upper 5-percentile benchmark scores on each distribution. For overall
assessment against all 15 criteria, “pressure” indicators could not score as highly as “state” indicators because scores
against four criteria were all automatically set to zero; hence the different distributions and benchmark thresholds
illustrated in Figure 1.5.5.1.4. When considering the operational implementation of each indicator, only data from six
criteria were used, giving the third distribution and set of benchmark scores. In this latter case all six criteria applied to
both “state” and “pressure” indicators, so both indicator types had the same distribution and benchmark thresholds. The
precise benchmark score thresholds are shown in Table 1.5.5.1.3. ICES considers that assessment scores falling above
the upper 5-percentile benchmark threshold identify statistically significant high-performing indicators.
Figure 1.5.5.1.4
Score distributions for 100 000 virtual indicators (for details see ICES, 2013b), showing mean (light
blue), upper 25-percentile (red), upper 10-percentile (blue), and upper 5-percentile (green) scores,
computed using randomly sampled categories (for score B) for state indicators (top), pressure
indicators (middle), and for the subset of categories that were considered to reflect the operational
implementation of each indicator (bottom).
Table 1.5.5.1.5
Summary of simulated indicators: mean and upper percentiles for the distribution of randomized
indicator scores.
Summary statistic
Mean
Upper 25 percentile
Upper 10 percentile
Upper 5 percentile
ICES Advice 2013, Book 1
State
0.500
0.578
0.656
0.688
Pressure
0.375
0.453
0.516
0.547
Operation
0.501
0.633
0.733
0.767
219
Table 1.5.5.1.6 shows the performance of the 35 common indicators against the benchmark thresholds for overall
performance, adequate coverage of the Greater North Sea MSFD sub-region, and for how close each is to becoming fully
operational. The analysis reflects the greater availability of appropriate fish community data and the relatively long history
of developing and using ecological indicators based on these data.
Table 1.5.5.1.6
Evaluation of the performance of the OSPAR common indicators against criteria 2 to 15; against the
six criteria related to the ability to use the indicators, and against the criterion related to spatial
coverage of the indicators. Green cells show where indicators meet the benchmark thresholds and
red cells show where indicators do not meet the benchmark thresholds. For abbreviation of indicators
see Table 1.5.5.1.4.
Common Indicator
M-1
M-2
M-3
M-4
M-5
M-6
B-1
B-2
B-3
B-4
B-5
B-6
FC-1
FC-2
FC-3
FC-4
BH-1
BH-2
BH-3
BH-4
BH-5
PH-1
PH-2
PH-3
FW-1
FW-2
FW-3
FW-4
FW-5
FW-6
FW-7
FW-8
FW-9
NIS-1
NIS-2
TOTAL
Overall
Operational
Spatial Coverage
17
14
19
MSFD indicators 1.4.1, 1.4.2, 1.5.1, 1.5.2, 1.6.1, 1.6.2, and 1.6.3 all relate to ‘habitat-level of biodiversity’, and so are
pertinent to both the benthic habitats and pelagic habitats ecosystem components, but not to birds, mammals, or fish.
Despite this, the ICG–COBAM Technical Specification document links two fish component indicators, the large fish
indicator (FC-2) and the mean maximum length (FC-3), to MSFD indicators 1.6.2 and 1.6.1, respectively. ICES considers
that it would be more appropriate for these OSPAR common indicators to be linked to the ecosystem/community level of
biodiversity covered by MSFD indicator 1.7.1 (a linkage is also specified in the ICG–COBAM Technical Specification
document).
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ICES Advice 2013, Book 1
Comments on indicators for non-indigenous species
•
•
•
•
•
•
•
•
The technical description of the proposed NIS-1 indicator is insufficiently detailed and is incomplete. ICES
considers that both the indicator and the description need further development.
The OSPAR common indicators for non-indigenous species (NIS) do not provide information to support
decisions on bioinvasion management options other than prevention. These include control, confinement, and
mitigation of invasive species (Lodge at al., 2006; Olenin et al., 2011).
It may be that country-specific indicators are more relevant to this issue than common indicators. The importance
of different pathways and vectors differ between countries and this should be considered when deciding on
appropriate common indicators (and in designing sampling, analysis, and assessments). An analysis should be
carried out, taking into account the importance of different pathways and associated vectors for each country
(see Olenin et al., 2010, 2011).
Sampling methodology should be designed in relation to the organism groups to be monitored. It is unclear from
the technical description for which organism groups/taxa/species monitoring will be planned, and therefore it is
at this stage impossible to review the proposed methodology. In general, a sampling frequency of once per year
is insufficient to obtain representative information for several organism groups, and is particularly poor for
planktonic organisms with a reproduction cycle merely ranging a few days.
The proposed site selection of two sites per country is likely to be insufficient. The site selection should be
country-specific and rather depend on the analysis of the presence and importance of different pathways/vectors.
ICES further suggests that the choice of monitoring location be based on likely entry points into regional seas.
To assess impacts caused by NIS, distribution, abundance, and biomass data are also needed. For this reason
also, more than two sites will need to be monitored.
A possible way to decide which invasion pathways and habitats should be monitored is preparing a
pathway/habitat matrix and leave the selection to individual countries based on their priorities and capabilities.
Species identification is likely to pose serious problems, particularly for smaller organisms such as the microzooplankton or meio-benthos.
The target setting should be redefined; a three-year period is likely to be too short, a longer assessment period is
more appropriate (e.g. six years, as stated in the MSFD Directive (EU, 2008)).
Sources
EU. 2008. Directive of the European Parliament and the Council Establishing a Framework for Community Action in the
Field of Marine Environmental Policy (Marine Strategy Framework Directive). European Commission. Directive
2008/56/EC, OJ L 164.
ICES. 2013a. Report of the Working Group on the Ecosystem Effects of Fishing Activities (WGECO), 1–8 May 2013,
Copenhagen, Denmark. ICES CM 2013/ACOM:25. 86 pp.
ICES. 2013b. Report of the Working Group on Biodiversity Science (WGBIODIV). ICES CM 2013/SSGEF:02. 62 pp.
ICES. 2013c. Report of the ICES Working Group on the Introduction and Transfers of Marine Organisms (WGITMO).
ICES CM 2013/ACOM:30. 150 pp.
ICES. 2013d. Report of the Working Group on Marine Habitat Mapping (WGMHM). In draft.
ICES. 2013e. Report of the Working Group on Marine Mammal Ecology (WGMME). ICES CM 2013/ACOM:26.
Lodge, D. M., Williams, S., MacIsaac, H. J., Hayes, K. R., et al. 2006. Biological invasions: recommendations for US
policy and management. Ecological Applications, 16: 2035–2054.
Olenin, S., Alemany, F., Cardoso, A. C., Gollasch, S., Goulletquer, P., Lehtiniemi, M., et al. 2010. Marine Strategy
Framework Directive – Task Group 2 Report. Non-indigenous species. European Communities. EUR 24342 EN.
ISBN 978-92-79-15655-7. ISSN 1018-5593. DOI 10.2788/87092. Luxembourg: Office for Official Publications of
the European Communities. 44 pp.
Olenin, S., Elliott, M., Bysveen, I., Culverhouse, P., Daunys, D., Dubelaar, G. B. J., et al. 2011. Recommendations on
methods for the detection and control of biological pollution in marine coastal waters. Marine Pollution Bulletin, 62
(12): 2598–2604.
OSPAR. 2013a. Report by ICG–COBAM on the development of an OSPAR common set of biodiversity indicators: Parts
A and B. BDC 13/4/2-E. 41 pp.
OSPAR. 2013b. Report by ICG–COBAM on the development of an OSPAR common set of biodiversity indicators: Part
C: Technical Specifications. BDC 13/4/2 Add.1-E. 156 pp.
Piet, G. J., Quirijns, F., Robinson, L., and Greenstreet, S. P. R. 2007. Potential pressure indicators for fishing and their
data requirements. ICES Journal of Marine Science, 64: 110–121.
ICES Advice 2013, Book 1
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1.5.6.4
Special request, Advice June 2013
ECOREGION
General advice
SUBJECT
OSPAR special request on maximizing the use of available sources of data
for monitoring of biodiversity
Advice summary
ICES advises that two of the major annual coordinated surveys, the International Bottom Trawl Survey and the Beam
Trawl Survey, used to provide information to support fish stock assessments, could also be used to provide information
for several Marine Strategy Framework Directive (MSFD) indicators. In these two surveys, a small amount of additional
sampling effort could deliver a much broader set of data.
ICES advises that an ecosystem monitoring programme should be developed. Such a programme should be designed not
only to observe status, but also to understand the processes underlying these observations, and the links between
ecosystem components and with the physical environment.
A further six existing surveys have the potential to collect appropriate data for nine of the eleven descriptors.
Request
The purpose of this request is to seek ICES advice on the potential sources of data and information that may be available
to support the monitoring and assessment of biodiversity in relation to commitments under MSFD so as to maximise
efficiencies in the use of available resources, for example:
-
-
where efficiencies could be made to identify where there are monitoring programmes or data sources that can
deliver multiple indicators, which may relate to different Descriptors, (e.g. The Data Collection Framework
could be used to implement D3 and D1 indicators), or
where with a small additional effort existing monitoring could be amplified to deliver a broader set of data.
Advice is sought as to 1) the quality of these potential data sources and how they could be used, including but not limited
to the relevance of outcomes identified in chapter 8 of the ICES MSFD D3+ report to Descriptors 1, 4 and 6.
(OSPAR request 4/2013)
ICES advice
Scientific surveys
Two major ICES coordinated annual surveys could, with relatively minor additional effort, be used to better inform the
assessment of the state of multiple OSPAR indicators, relevant to several MSFD descriptors. For the International Bottom
Trawl Survey, the main areas where data are available already are the Fish and Cephalopod indicators FC-1 to FC-8 18,
with the exception of indicator 4 (on bycatch). Additional data products would be available contingent on a number of
procedural developments, including the development of swept area estimation procedures and appropriate maturity
estimation keys. Data support could be provided for Foodweb indicators (FW-4 and FW-7). FW-8 could be supported in
terms of stomach sampling. For Bird indicators, the surveys could provide seabird data for indicator B-6, but it is
suggested that this is more appropriate for other survey types (e.g. acoustic and icthyoplankton).
For the Beam Trawl Survey, the conclusions in terms of the FC indicators are broadly similar, although swept area
estimates are much more straightforward with this gear, and could be improved with use of covariates. No data for FC-6
is obtainable due to survey timing, but improvements could be made with new maturity keys and at-sea histological
sampling. Biomass and abundance estimates of taxa that can be caught by the survey could support FW-4, FW-7, and
FW-8. Again, the surveys could provide seabird data for indicator B-6, but it is suggested that this is more appropriate for
other survey types (e.g. acoustic and icthyoplankton).
18
222
FC, FW, M, B, BH, PH, and NIS refer to the ICG–COBAM indicator numbering.
ICES Advice 2013, Book 1
The combined response table to the OSPAR request for the two surveys is presented in Table1.5.5.2.1 (data availability)
and Table 1.5.5.2.2 (possible improvements).
ICES Advice 2013, Book 1
223
Table 1.5.5.2.1
EU
Indicator
ID
1.2.1
Possible contributions of the ICES International Bottom Trawl Surveys (IBTS) and Beam Trawl Surveys (BTS) to reporting under the MSFD, with regard to biodiversity-related
indicators. The selected indicators are based on nomenclature in the EU Decision (COM 477/2010) and matching OSPAR indicator ID (2nd column). IBTS applies only to the
North Sea and Northeast Atlantic; BTS is conducted in all areas except the Northeast Atlantic.
OSPAR
Indicator ID
FC-1
Core
Name
Population abundance/
biomass of a suite of
selected species.
Survey
IBTS
BTS
4.2.1
3.3.2
N.A.
(related to
4.3.1)
FC-2; FW-3
Core
FC-3
Core
FC-5
Candidate
OSPAR EcoQO for
proportion of large fish
(LFI).
IBTS
BTS
Mean maximum length IBTS
of demersal fish and
elasmobranchs.
BTS
Conservation status of
elasmobranch and
demersal bony-fish
species (IUCN).
IBTS
BTS
1.3.1;
3.3.1
224
FC-6
Candidate
Proportion of mature
fish in the populations
of all species sampled
adequately in
international and
national fish surveys.
IBTS
North Sea
Northeast Atlantic
Abundance estimates (per
hour and per km2) of various
fish species. Accuracy is
species-dependent.
Abundance (per km2)
estimates for various fish
species can be supplied.
Accuracy is speciesdependent.
Abundance estimates (per
hour and per km2) of various
fish species. Accuracy is
species-dependent.
Main source of data for this
indicator.
Main source of data for this
indicator. Cut-off point and
reference limit needs to be
defined by the survey.
Main source of data for this
indicator.
Main source of data for this
indicator
Abundance estimates (per
hour and per km2) of various
fish species. Accuracy is
species-dependent.
Abundance (per km2)
estimates for various fish
species can be supplied.
Accuracy is speciesdependent.
Main source of data for this
indicator.
Main source of data for IBTS
target species, but depending
on species-specific
maturation process and
hence sampling time
(quarter).
Data availability
Western shelf
France/Biscay
Inshore
Abundance (per km2)
estimates for various fish
species can be supplied.
Accuracy is speciesdependent.
Abundance (per km2)
estimates for various fish
species can be supplied.
Accuracy is speciesdependent.
The area covered is spatially
restricted but will give
additional information not
available from other survey
sources. Abundance (per
km2) estimates for various
fish species can be supplied.
Accuracy is speciesdependent.
Main source of data for this
indicator. Cut-off point and
reference limit needs to be
defined by the survey.
Main source of data for this
indicator. Cut-off point and
reference limit needs to be
defined by the survey.
Main source of data for this
indicator. Cut-off point and
reference limit needs to be
defined by the survey.
Main source of data for this
indicator
Main source of data for this
indicator
Main source of data for this
indicator
Abundance (per km2)
estimates for various fish
species can be supplied.
Accuracy is speciesdependent.
Abundance (per km2)
estimates for various fish
species can be supplied.
Accuracy is speciesdependent.
The area covered is spatially
restricted but will give
additional information not
available from other survey
sources. Abundance (per
km2) estimates for various
fish species can be supplied.
Accuracy is speciesdependent.
Main source of data for this
indicator.
Abundance estimates (per
hour and per km2) of various
fish species. Accuracy is
species-dependent.
Main source of data for IBTS
target species, but depending
on species-specific
maturation process and
hence sampling time
(quarter).
ICES Advice 2013, Book 1
EU
Indicator
ID
1.1.1
1.1.2
possibly
related to
1.7.1 or
4.3.1
1.7.1;
4.3.1
OSPAR
Indicator ID
FC-7
Candidate
FC-8
Candidate
FW-4
Core
FW-7
Candidate
Name
Survey
North Sea
Distributional range of
a suite of selected
species.
IBTS
Distributional pattern
within the range of a
suite of selected
species.
Changes in average
trophic level of marine
predators.
IBTS
Fish biomass and
abundance of dietary
functional groups.
IBTS
BTS
BTS
IBTS
BTS
BTS
could be
related to
4.2.1;
4.3.1
FW-8
Candidate
Changes in average
faunal biomass per
trophic level (biomass
trophic spectrum).
ICES Advice 2013, Book 1
IBTS
BTS
Main source of data for this
indicator.
Main source of data for this
indicator.
Main source of data for this
indicator.
Main source of data for this
indicator.
Calculation of relative
abundance is possible.
Calculation of relative
abundance is possible.
Biomass and abundance
estimates (per hour or per
km2) of various fish species.
Biomass and abundance
estimates per km2 of various
fish species.
Data on biomass per haul for
all fish species.
Data on biomass per haul for
fish species and benthic
organisms available for some
surveys and some years.
Northeast Atlantic
Data availability
Western shelf
France/Biscay
Inshore
Main source of data for this
indicator.
Main source of data for this
indicator.
Main source of data for this
indicator.
Main source of data for this
indicator.
Main source of data for this
indicator.
Main source of data for this
indicator.
Main source of data for this
indicator.
Calculation of relative
abundance is possible.
Calculation of relative
abundance is possible.
Calculation of relative
abundance is possible.
Biomass and abundance
estimates per km2 of various
fish species.
Biomass and abundance
estimates per km2 of various
fish species.
Biomass and abundance
estimates per km2 of various
fish species.
Main source of data for this
indicator.
Calculation of relative
abundance is possible.
Biomass and abundance
estimates (per hour or per
km2) of various fish species
Data on biomass per haul for
all fish species.
Data on biomass per haul for
fish species and benthic
organisms available for some
surveys and some years.
Data on biomass per haul for
fish species available.
Epibenthic biomass available
for some surveys.
225
Table 1.5.5.2.2
EU
Indicator
ID
1.2.1
Possible improvements to the ICES International Bottom Trawl Surveys (IBTS) and Beam Trawl Surveys (BTS) in reporting under the MSFD, with regard to biodiversity-related
indicators. The selected indicators are based on nomenclature in the EU Decision (COM 477/2010) and matching OSPAR indicator ID (2nd column). IBTS applies only to the
North Sea and Northeast Atlantic; BTS is conducted in all areas except the Northeast Atlantic. The possible improvement of data availability in each of the survey areas, if extra
effort is allocated to these surveys, is indicated.
OSPAR
Indicator ID
FC-1
Core
Name
Population
abundance/
biomass of a
suite of selected
species.
Survey
IBTS
BTS
1.3.1;
3.3.1
Poss.
related to
1.7.1 or
4.3.1
FC-6
Candidate
FW-4
Core
226
For some species that are presently
not always reported to species level
(e.g. squids, gobies), species could
be collected for taxonomic ID on
shore.
Precision could be improved
through further development of
sampling and statistical techniques.
For some species that are presently
not always reported to species level
(e.g. squids, gobies), species could
be collected for taxonomic ID on
shore.
For additional species theoretically
possible, but requires extra
resources for acquisition of maturity
data. Guidelines needed for
maturity keys / spawning times.
Precision could be improved by
further development of analysis of
maturity.
Changes in
average trophic
level of marine
predators.
Samples for fish predators can be
provided on a regular basis (using
stomach analyses or tissue samples
for stable isotope analysis); sample
processing requires extra analytical
effort.
Samples for fish predators can be
provided (for stomach analyses or
tissue samples for stable isotope
analysis); sample processing
requires extra analytical effort.
BTS
1.7.1; 4.3.1 FW-7
Candidate
Northeast Atlantic
Proportion of
IBTS
mature fish in the
populations of all
species sampled
adequately in
international and BTS
national fish
surveys.
IBTS
Fish biomass and IBTS
abundance of
dietary functional
groups.
BTS
Possible improvement with extra effort
Western shelf
North Sea
Individual fish weights of nontarget species could be provided
with extra effort.
Individual fish weights of nontarget species could be provided
with extra effort.
France/ Biscay
Inshore
Precision could be
improved through further
development of sampling
and statistical techniques.
Precision could be
improved through further
development of sampling
and statistical techniques.
Precision could be
improved through further
development of sampling
and statistical techniques.
Precision could be
improved by further
development of analysis of
maturity.
Precision could be
improved by further
development of analysis of
maturity.
Samples for fish predators
can be provided (for
stomach analyses or tissue
samples for stable isotope
analysis); sample
processing requires extra
analytical effort.
Samples for fish predators
can be provided (for
stomach analyses or tissue
samples for stable isotope
analysis); sample
processing requires extra
analytical effort.
Samples for fish predators
can be provided (for
stomach analyses or tissue
samples for stable isotope
analysis); sample
processing requires extra
analytical effort.
Individual fish weights of
non-target species could be
provided with extra effort.
Individual fish weights of
non-target species could be
provided with extra effort.
Individual fish weights of
non-target species could be
provided with extra effort.
ICES Advice 2013, Book 1
EU
OSPAR
Indicator
ID
Indicator ID
could be
FW-8
related to
Candidate
4.2.1; 4.3.1
1.1.2
B-6
Core
ICES Advice 2013, Book 1
Name
Survey
North Sea
Changes in
average faunal
biomass per
trophic level
(biomass trophic
spectrum).
Distributional
pattern of
breeding and
non-breeding
marine birds.
IBTS
BTS
IBTS
BTS
Full benthic sort and sampling
possible with extra resources.
Northeast Atlantic
Possible improvement with extra effort
Western shelf
Full benthic sort and
sampling possible with
extra resources.
France/ Biscay
Inshore
Full benthic sort and
sampling possible with
extra resources.
Full benthic sort and
sampling possible with
extra resources.
Some vessels may be able to take
bird observers aboard.
Some vessels may be able to take
bird observers aboard.
227
A further four surveys can provide information suitable for use in evaluating ecosystem indicators; one of these is outside
the area of EU waters:
• Norwegian Barents Sea survey – trawl, acoustic, and ecosystem survey.
• French Biscay Pelagic ecosystem survey – acoustic.
• German mackerel egg survey – icthyoplankton.
• Scottish Nephrops TV survey.
ICES analysed the strengths and weaknesses of these surveys and two key themes emerged:
•
•
setting and prioritizing objectives;
survey design and the need to be able to elucidate process by explicitly linking dynamics in different ecosystem
components.
Some of the strengths were mutually exclusive, either operationally or conceptually, and therefore an ‘ideal ecosystem
survey’ on a single vessel, is unlikely to exist. The prioritization of surveys might be based on three factors:
•
•
the characteristics of the ecosystem, particularly with respect to the spatial and temporal scales of variability.
the available resources in ship time, but also expertise and financial considerations. International pooling of
resources will aid to increase efficiency and improve regional ecosystem assessments across national boundaries.
• the management and legal requirements and prioritizations for reporting. This is not a scientific criterion, but an
ability to address the former will almost certainly have an impact on the availability of resources.
Acoustic surveys may represent the best option for collecting data to evaluate the Pelagic Habitat (PH) indicators, and
also some Benthic Habitat (BH) indicators by acoustic means including multi-beam technology. TV surveys can support
BH-1, BH-3, BH-4, and FW-9. Icthyoplankton surveys provide potential to help evaluate both pelagic habitat and
foodweb indicators. These surveys are also better platforms for the collection of data on birds and mammals at sea
compared with slower trawl surveys.
Integrated monitoring
There are considerable benefits to designing and developing a cost-effective integrated monitoring programme that can
address the existing information needs and those of MSFD in comparison with current discipline-specific monitoring
programmes. The former may provide advice based on an understanding of ecosystem processes, which can help in
identifying how to act rather than merely identifying current status in separate parts of the ecosystem.
As none of the individual surveys can provide all the information that would be required to service the full suite of OSPAR
common indicators, it makes the concept of clustering indicators rather difficult to put into practice. Perhaps the most
effective cruise, if it were possible to organise, would be a bottom trawl survey where, in addition to the standard fish
sampling:
•
•
•
•
•
•
•
Stomach and biological samples of a wide range of taxa were collected;
Seabed habitat acoustic survey data were collected between fishing stations;
Seabirds and marine mammals at sea were surveyed between fishing stations;
A continuous plankton recorder was deployed while the vessel was underway between stations;
Hydrographic data were collected continuously by on-board autonomous samplers;
CTD data and water and plankton samples were collected at each sampling station;
The night-time period was utilized to sample benthic invertebrates.
Such a survey would collect data that could potentially service 65% of the OSPAR common indicators (M-2, M-4, B-1,
B-6, FC-1, FC-2, FC-3, FC4, BH-1, BH-2, BH-5, PH-1, PH-2, PH-3, FW-2, FW-3, FW-4, FW-5, FW-6, FW-7, FW-8,
FW-9, and NIS-2).
228
ICES Advice 2013, Book 1
Background
This advice has focussed on research vessel surveys as potential sources of data. Other potential data sources include:
•
•
•
•
•
•
Commercial landings data and logbooks.
Commercial discard data (that will cease when discard bans come into force).
Shore-based sampling, particularly for benthos, contaminants, hydrographic parameters and biological
oceanography.
Remote sensing i.e. satellites for e.g. sea surface temperature, ocean colour, sea surface elevation, waves, etc.
Sea-going sampling systems such as continuous plankton recorders on platforms of opportunity, underwater
cameras, etc.
Aerial surveys (marine mammals, sea turtles, seabirds, sharks).
Several ICES expert groups have been developing analyses of the opportunities for wider usage of fisheries research
surveys (ICES, 2010a, 2010b, 2012a, 2012b, 2013a, 2013b, 2013c, 2013d).
The request also refers to the Data Collection Framework (DCF) indicators used to evaluate the ecosystem impacts of
fishing. Four of these in particular are relevant to MSFD indicators:
• Conservation status of fish species (FC-5).
• Proportion of large fish (FC-2, FW-3).
• Mean maximum length of fishes (FC-3).
• Size-at-maturation of exploited fish species (FC-6).
ICES has recently advised the European Commission on this topic (ICES, 2013e).
Table 1.5.5.2.3 summarizes some suggestions on how surveys may be adapted to fulfil the needs of OSPAR.
.
ICES Advice 2013, Book 1
229
ICES COORDINATED SURVEYS
Fi s h s urveys us i ng nets (BTS, IBTS, etc)
Acous ti c fi s h s urveys
Vi deo s urveys (Nephrops )
Ichthyopl a nkton s urveys (fi s h l a rva e)
230
MAMMALS
A
A
A
A
BIRDS
A
A
FISH & CEPH
E E E
E
BENTHIC HAB.
PEL. HAB.
A A A A A A A A
A A A
A
A A
A A A
A
A
A
A
E
A
E
A
A
A
A
A
NIS-2 (Rate of new introductions of NIS)
NIS-1 (pathways management measures)
FW-9 (Ecological Network Analysis)
FW-8 (Biomass Trophic Spectrum)
FOOD WEBS
E A A A
A A
FW-7 (fish biomass and dietary functional groups)
FW-6 (zooplankton)
FW-5 (change funct groups plankton)
FW-4 (change in average trophic level of predators)
FW-3 (Large Fish Indicator)
FW-2 (production of phytoplankton)
FW-1 (repr success in relation to food avail)
PH-3 (changes biodiv index)
PH-2 (biomass/abundance)
PH-1 (changes functional types)
BH-5 (size-freq sensitive species)
BH-4 (area habitat loss)
BH-3 (damage)
BH-2 (multimetric indices)
BH-1 (typical species)
FC-4 (bycatch Chondrichthes)
FC-3 (mean max length)
FC-2 (LFI)
FC-1 (abundance/biomass)
B-6 (distribution)
B-5 (bycatch)
B-4 (mammals on seabird colonies)
B-3 (breeding success/failure marine birds)
B-2 (breeding success kitiwake)
B-1 (trends in species)
M-6 (bycatch)
M-5 (seal pup production)
M-4 (abundance cetaceans)
M-3 (abundance grey & harbour seals)
M-2 (range pattern cetaceans)
M-1 (range pattern grey & harbour seals)
Table 1.5.5.2.3
Summary of the OSPAR “common indicators” that could potentially be serviced using data derived from the additional (A) ecological sampling that might be feasible during
different types of fisheries surveys. E = Existing data collection. Candidate indicators FC-5 to FC-8 are not shown as no technical specifications for these have been supplied to
ICES. It may be that some surveys could help in data collection against these indicators.
ALIENS
A
A
A
ICES Advice 2013, Book 1
Sources
ICES. 2010a. Report of the Working Group on Integrating Surveys for the Ecosystem Approach (WGISUR), 26–28
January 2011, Dublin, Ireland. ICES CM 2010/SSGESST:08. 17 pp.
ICES. 2010b. Report of the Workshop on Cataloguing Data Requirements from Surveys for the EAFM (WKCATDAT),
26–28 January 2011, Dublin, Ireland. ICES CM 2010/SSGESST:09. 38 pp.
ICES. 2012a. Report of the Working Group on Integrating Surveys for the Ecosystem Approach (WGISUR), 24–26
January 2012, Ijmuiden, the Netherlands. ICES CM 2012/SSGESST:20. 24 pp.
ICES. 2012b. Report of the Workshop on Evaluation of Current Ecosystem Surveys (WKECES), 20–22 November 2012,
Bergen, Norway. ICES CM 2012/SSGESST:23. 59 pp.
ICES. 2013a. Report of the International Bottom Trawl Survey Working Group (IBTSWG), 8–12 April 2013, Lisbon,
Portugal. ICES CM 2013/SSGESST:10.
ICES. 2013b. Report of the Working Group on Beam Trawl Surveys (WGBEAM), 23–26 April 2013, Ancona, Italy.
ICES CM 2013/SSGESST:12.
ICES. 2013c. Report of the Working Group on the Ecosystem Effects of Fishing Activities (WGECO), 1–8 May 2013,
Copenhagen, Denmark. ICES CM 2013/ACOM:25. 86 pp.
ICES. 2013d. Report of the Working Group on Biodiversity Science (WGBIODIV). ICES CM 2013/SSGEF:02. 62 pp.
ICES. 2013e. Report of the ICES Advisory Committee. ICES Advice, 2013. Book 1, Section 1.5.2.1.
ICES. 2013f. Report of the ICES Working Group on the Introduction and Transfers of Marine Organisms (WGITMO).
ICES CM 2013/ACOM:30. 150 pp.
ICES. 2013g. Report of the Working Group on Marine Habitat Mapping (WGMHM). In draft.
Supplementary background documentation is available at:
https://groupnet.ices.dk/wgeco2013/default.aspx?RootFolder=%2fwgeco2013%2fReport%202013%2fToR%20C&Fold
erCTID=&View=%7b63F03C99%2d9F39%2d457D%2d8135%2d25A0BEA67AAF%7d
ICES Advice 2013, Book 1
231
1.5.6.5
Special request, Advice June 2013
ECOREGION
SUBJECT
General advice
OSPAR/NEAFC special request on review of the results of the Joint
OSPAR/NEAFC/CBD Workshop on Ecologically and Biologically
Significant Areas (EBSAs)
Advice summary
ICES reviewed the ecological evidence supporting the ten proposed ecologically and biologically significant areas
(EBSAs) from the OSPAR/NEAFC/CBD Workshop of September 2011, as presented in the annexes to that report. The
review applied standard ICES practices and used primarily the references cited in the relevant annexes, but augmented
those references with other publications and data sources. In nine of the ten proposed EBSAs, ICES came to different
conclusions than were contained in the OSPAR/NEAFC/CBD Workshop report, with regard to the rankings of the
Convention on Biological Diversity (CBD) EBSA criteria.
Of the ten proposed EBSAs, ICES supports the conclusion of the OSPAR/NEAFC/CBD workshop that the Arctic Ice
area (Area 10) meets one or more EBSA criteria and this area could go forward at this time, possibly with minor suggested
changes to the rationale.
In four proposed EBSAs (Reykjanes Ridge south of Iceland EEZ (Area 1); Charlie-Gibbs Fracture Zone and Subpolar
Frontal Zone of the Mid-Atlantic Ridge (Area 2); Mid-Atlantic Ridge north of the Azores (Area 3); the Hatton and Rockall
banks and Hatton–Rockall Basin (Area 4)), ICES considers that much of the area within the proposed EBSAs do not meet
any of the EBSA criteria and for this reason the boundaries of these proposals need to be revised. More restricted parts of
the proposed EBSAs meet several of the EBSA criteria and could go forward after boundary revision. ICES notes great
similarities in the pro forma describing Areas 1 and 3 and part of Area 2 (OSPAR/NEAFC/CBD, 2011). A boundary
revision to encompass the relevant parts of these areas as a single extended Mid-Atlantic Ridge proposed EBSA could be
considered a step forwards. ICES recommends changes also to the pro forma rankings for all of these proposed EBSAs.
Only a small part of the proposed EBSA for the Arctic Front – Greenland/Norwegian seas (Area 9) possibly meets some
of the EBSA criteria. However, another part of the general area might meet some of the EBSA criteria. ICES recommends
that further data analyses followed by an evaluation of the new results against the EBSA criteria be undertaken before
any further decision is taken.
The rationales for four proposed EBSAs (around the Pedro Nunes and Hugo de Lacerda seamounts (Area 5); Northeast
Azores–Biscay Rise (Area 6); Evlanov Seamount region (Area 7); and Northwest of Azores EEZ (Area 8)) are not well
supported by the information presented in the relevant annexes. There is a need for further data and analyses in these
areas, particularly in relation to seabirds, and another evaluation of the areas against the EBSA criteria.
ICES found no clear evidence of additional EBSAs in areas beyond national jurisdiction (ABNJ) of the Northeast Atlantic
meeting the CBD scientific criteria.
Request
a) Review the description of areas meeting one or more of the CBD EBSA scientific criteria developed as an outcome of
the Joint OSPAR/NEAFC/CBD Scientific Workshop, in particular:
1. Review each of the ten area delineations and descriptions in line with the CBD EBSA Scientific criteria and
the most up-to-date scientific data and information, specifying any additional scientific data and information
that is available;
2. Provide, if appropriate, revised EBSA proposals in the format of proformas adopted by the CBD
b) If there is clear evidence for additional areas in ABNJ of the North-East Atlantic meeting the CBD EBSA scientific
criteria, present a description with supporting scientific data and information for such areas, including CBD EBSA
proformas for each.
ICES advice
ICES made the following conclusions and proposals.
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ICES Advice 2013, Book 1
Area 1. Reykjanes Ridge south of Iceland EEZ: Much of the area in the proposed EBSA does not meet any of the EBSA
criteria. A more restricted area down the spine of the Mid-Atlantic Ridge and defined by depth ranges of deep-water coral
and sponge concentrations does meet several EBSA criteria and the boundary delineation, ranking, and full rationale
could be developed based on this new boundary.
Area 2. Charlie-Gibbs Fracture Zone and Subpolar Frontal Zone of the Mid-Atlantic Ridge: Some areas in the proposed
EBSA do not meet any of the EBSA criteria. A complex combination of the area down the spine of the Mid-Atlantic
Ridge, the benthic area aligned with and close to the main fractures, and the water column in which the Subpolar Front is
found throughout the year, does meet several EBSA criteria and the boundary delineation, ranking and full rationale could
be developed at based on this new boundary.
Area 3. Mid-Atlantic Ridge north of the Azores: Much of the area in the proposed EBSA does not meet any of the EBSA
criteria. A more restricted area down the spine of the Mid-Atlantic Ridge and defined by depth ranges of deep-water coral
and sponge concentrations does meet several EBSA criteria and the boundary delineation, ranking, and full rationale
could be developed based on this new boundary.
Area 4. The Hatton and Rockall banks and Hatton–Rockall Basin: Much of the area in the proposed EBSA does not meet
any of the EBSA criteria. A more restricted area down to approximately 1500–1800 m depth, but excluding the abyssal
plain does meet several EBSA criteria and the boundary delineation, ranking, and full rationale could be developed based
on this new boundary.
Area 5. Around the Pedro Nunes and Hugo de Lacerda seamounts: The proposed EBSA is not supported well by the
information presented in the pro forma. There is a need for further analyses of those data already considered, as well as
any additional relevant data on seabird foraging and other information. When these analyses are done, including for the
additional data, another evaluation of the area against the CBD EBSA criteria would make it possible to advise which
areas, if any, meet EBSA criteria.
Area 6. Northeast Azores–Biscay Rise: The proposed EBSA is not supported well by the information presented in the pro
forma. There is a need for further analyses of those data already considered as well as any additional relevant data on
seabird foraging and other information. When these analyses are done, including for the additional data, another
evaluation of the area against the CBD EBSA criteria would make it possible to advise which areas, if any, meet EBSA
criteria.
Area 7. Evlanov Seamount region: The proposed EBSA is not supported well by the information presented in the pro
forma. There is a need for further analyses of those data already considered as well as any additional relevant data on
seabird foraging and other information. When these analyses are done, including for the additional data, another
evaluation of the area against the CBD EBSA criteria would make it possible to advise which areas, if any, meet EBSA
criteria.
Area 8. Northwest of Azores EEZ: The proposed EBSA is not supported well by the information presented in the pro
forma. There is a need for further analyses of those data already considered as well as any additional relevant data on
seabird foraging and other information. When these analyses are done, including for the additional data, another
evaluation of the area against the CBD EBSA criteria would make it possible to advise which areas, if any, meet EBSA
criteria.
Area 9. The Arctic Front – Greenland/Norwegian seas: Only a small part of the area proposed by the
OSPAR/NEAFC/CBD Workshop as an EBSA was considered to possibly meet some of the criteria. However, another
part of the general area might meet some EBSA criteria. There is a need for more analyses of productivity and diversity
data for the more southerly part of the main area, and then a re-evaluation of the new results against the EBSA criteria,
before any areas might be considered as possibly meeting EBSA criteria.
Area 10. The Arctic Ice: The rationale for concluding that this area meets one or more EBSA criteria can be improved,
but the review by ICES generally supports the conclusions of the OSPAR/NEAFC/CBD workshop. A suggested revised
proforma is attached as Annex 1.5.6.5.1 to this advice.
With regard to new proposed areas that meet EBSA criteria, ICES has no additional information. However, ICES suggests
a potential alternative configuration to the areas in proposed EBSAs 1, 2, and 3 that would comprise two areas meeting
EBSA criteria, one covering the specified depths of the entire Mid-Atlantic Ridge, and one for the Charlie-Gibbs Fracture
Zone and pelagic area of the Subpolar Front. Each of the two areas would have coherent, but different ecological
rationales.
ICES has provided its rankings for the revised proposed EBSAs and the rationale for those rankings. ICES has not revised
the narrative or the references in the existing pro forma of proposed EBSAs other than for Arctic Ice habitat (Annex
ICES Advice 2013, Book 1
233
1.5.6.5.1). Once OSPAR and NEAFC have made a decision on the configuration of the Mid-Atlantic Ridge proposed
EBSAs, ICES could revise the pro forma for these EBSAs by the end of September 2013.
Background
Method
ICES conducted its review informed by the content of the CBD Decisions IX/20 and X/29 on Marine and Coastal
Biodiversity (CBD, 2008, 2010), the reports from the ‘Azores Workshop’ (CBD, 2007) and the ‘Ottawa Workshop’
(CBD, 2009), and the UNGA Resolution 58/240 (United Nations, 2004). ICES considers that the application of the criteria
was intended to be a comparative or relative process, such that areas should be evaluated against other generally
comparable areas (e.g. of comparable depth and latitude). In addition, even though the application of EBSA criteria is not
guided directly by management considerations, potential benefits of spatial management measures are a relevant
consideration in the evaluation. However, the appropriate baseline is not the absence of all management, but the presence
of measures sufficient to ensure human uses are sustainable in areas typical of the zone of evaluation.
ICES is responding to a request about EBSAs, and ICES stresses that this advice does not imply that any areas reviewed
should or should not be considered as VMEs (but ICES notes that there is an overlap with advice provided recently on
vulnerable marine ecosystems (VMEs; ICES, 2013a)). ICES notes that all areas found to meet criteria for VMEs would
be expected to meet one or more criteria for EBSAs as well. However, the reverse is not necessarily true and EBSAs do
not necessarily contain VMEs. There is neither a policy nor an ecological rationale for automatically excluding bottom
fishing (or any other activity) from areas proposed as EBSAs. The expected initial response of regulatory authorities is to
conduct risk or threat assessments of the activities they regulate relative to the properties considered ecologically or
biologically significant, and to subsequently undertake management appropriate to the outcome of these assessments.
ICES advice is based on applying several standards during its review, including:
•
•
•
•
•
Assigned rankings on a criterion should apply to at least most of the area included in a proposed EBSA, and not just
to a small subset of the total area.
Higher assigned rankings required the proposed area to differ from adjacent areas and other areas of similar depth
and latitude on the property represented by the criterion.
Some evidence must be available to justify awarding a higher ranking, noting that comprehensive data for the high
seas cannot be expected.
Rankings should not be based on the presence or history of threats to the features represented by the criteria, but on
the biological, ecological, and geomorphological features of the area.
Although EBSAs are not defined by or linked to any particular management actions by any authorities, it is
appropriate to consider whether or not spatial management tools might benefit the conservation or sustainable use of
the relevant features.
For each of the ten areas in the OSPAR/NEAFC/CBD report proposed to meet EBSA criteria, ICES assigned one of three
categories:
•
•
Proceed with boundaries proposed by the OSPAR/NEAFC/CBD Workshop, with a rationale revised by ICES.
Proceed with developing a proposed EBSA with different boundaries than those proposed by the
OSPAR/NEAFC/CBD Workshop, and with a rationale provided by ICES.
• Do not proceed with proposing an EBSA at this time, but rather undertake further collation and analysis of
information and reconsider when the additional work is completed.
Although ICES review included an evaluation and commentary on all pro forma contents of the OSPAR/NEAFC/CBD
2011 Workshop report, this advice presents only ICES conclusions as to whether the areas meet the EBSA criteria. This
advice takes the form of biological properties that ICES concludes would define the boundaries, rankings, and rationales
of those areas against the EBSA criteria.
Proposed EBSAs that need minor revisions to the rationale
Area 10. The Arctic Ice
A suggested revised pro forma is attached to this advice as Annex 1.5.6.5.1.
Proposed EBSAs that should have redefined boundaries before proceeding
Area 1. Reykjanes Ridge south of Iceland EEZ
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ICES Advice 2013, Book 1
ICES advises that an area along the Reykjanes Ridge can be justified as meeting one or more EBSA criteria. This would
be a much smaller area than the one proposed in the OSPAR/NEAFC/CBD Workshop report. Appropriate boundaries for
such a proposed area that meets EBSA criteria would be a depth contour that runs in the deeper of two properties:
3.
4.
Including a large portion (arbitrarily, perhaps 90%) of all hard volcanic substrates; habitats are reported to host
the larger known coral formations and their associated communities
Including a large portion (arbitrarily, 90%) of the records of large sponge communities in the overall northern
Mid-Atlantic Ridge.
In addition, the proposed area will include the only known hydrothermal vent in the area (Olafsson et al., 1991; German
et al., 1994; German and Parsons, 1998; Mironov and Gebruk, 2007), whatever depth contour is used. Information on
water masses should also be consulted, allowing proper identification of benthic and fish fauna to be included in a revised
narrative to a pro forma for this area.
In the time available ICES did not have the geological data to delineate the depth contour that would meet the first
criterion, but such information should be readily available in marine geology databases. Nor did ICES have access to all
of the records of where the large sponge deposits were taken. However, references to sources for those data are in the
OSPAR/NEAFC/CBD Workshop pro forma and should be tracked back to find the appropriate depth contour for the
second criterion in the tables below.
Evaluation of the revised area against the EBSA criteria
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Know
The area contains either (i) unique
(“the only one of its kind”), rare
(occurs only in few locations), or
endemic species, populations, or
communities, and/or (ii) unique,
rare, or distinct habitats or
ecosystems, and/or (iii) unique or
unusual
geomorphological
or
oceanographic features.
Explanation for ranking
Uniqueness
rarity
or
Low
Some
High
X
(X)
The bracketed “High” ranking is for a very restricted area covering the only known hydrothermal vent on the Reykjanes
Ridge. Though this is a unique feature it occupies only a small part of the area proposed here as meeting this EBSA
criterion (Olafsson et al., 1991; German et al., 1994; German and Parsons, 1998; Mironov and Gebruk, 2006).
The MarEco sampling of corals and sponges reported a few species new to science and these may be restricted to the
proposed area, although a firm conclusion on this cannot be drawn until more extensive sampling is undertaken.
Areas that are required for a
Special
X
importance for population to survive and thrive.
life-history
stages of species
Explanation for ranking
Although many populations undoubtedly complete their life cycles within the large area proposed in the
OSPAR/NEAFC/CBD Workshop Report as an EBSA, this would be true of any marine area of comparable size. There
is no evidence that the life history of any species is strongly dependent on any specific features of the area proposed
as an EBSA.
There is evidence from other areas of the Northeast Atlantic that areas of high coral density may be important as eggcase and nursery areas of deep-water sharks and rays. The area proposed here is targeted on the depths and substrates
associated with higher coral and sponge densities, and if sharks and rays also concentrate spawning and early
development in these habitats, then the score would be “Some” or “High” on this criterion as well.
Importance for Areas containing habitats for the
X
survival
and
recovery
of
threatened,
threatened,
or
endangered, or endangered,
declining species, or areas with
ICES Advice 2013, Book 1
235
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Know
Low
Some
High
declining species significant assemblages of such
species.
and/or habitats
Explanation for ranking
Large formations of corals and sponges are found in the area proposed by ICES as meeting this criterion. Habitats
containing these species are listed by OSPAR and also feature as VME indicator species; the majority of these would
be included in the proposed EBSA. Additional explanation regarding corals and sponges is included in the rationale
for the criterion on Vulnerability.
The possible role of the area proposed by ICES in the life histories of sharks and rays is discussed in the criterion on
Vulnerability and Sensitivity.
Areas that contain a relatively high
Vulnerability,
X
proportion of sensitive habitats,
fragility,
sensitivity,
or biotopes, or species that are
functionally
fragile
(highly
slow recovery
susceptible to degradation or
depletion by human activity or by
natural events) or with slow
recovery.
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CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Know
Low
Some
High
Explanation for ranking
With regard to corals and sponges, Mortensen et al. (2008) found cold-water corals “at every sample station …
observed at depths between 800 and 2400 m, however were commonly found shallower than 1400 m …, with species
richness being very high. … no major reef structures were recorded, with the maximum colony size approximately 0.5
m in diameter. The number of coral taxa was strongly correlated with the percentage cover of hard bottom substrate
….” The area proposed here is targeted at the seamount peaks and slopes where hard substrates dominate. For sponges,
no actual large expanses of sponge reef were reported in the OSPAR/NEAFC/CBD Workshop report. However, the
pro forma in that report (OSPAR/NEAFC/CBD, 2011) notes that overall sampling of the area is patchy and cites three
studies that found local patches with high densities of sponges, although in no cases were the sizes of the patches
documented.
These observations of widespread occurrences of corals and sponges are supported by the records in the GRID–Arendal
data, which show both taxa to be presented in nearly every appropriate sample taken along the cruise tracks in the
database.
Biological
productivity
Areas containing species,
populations, or communities
with comparatively higher
natural biological productivity.
X
Explanation for ranking
Although benthic productivity of the proposed smaller EBSA may be higher than benthic productivity on the abyssal
plain, productivity integrated over the entire water column and seafloor seems typical of systems of comparable depth
and latitude globally.
Areas
containing
a
Biological diversity
X
comparatively higher diversity
of
ecosystems,
habitats,
communities, or species, or
with higher genetic diversity.
ICES Advice 2013, Book 1
237
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Know
Low
Some
High
Explanation for ranking
The possible, but incompletely documented presence of large coral and sponge stands, and the documented high
diversity of benthic and associated fish when corals or sponges are present in moderate or high density imply that some
areas may have high diversity. Aside from these benthic communities of somewhat restricted distribution, the
biodiversity otherwise appears typical of biotic communities at similar depths and latitude.
Area 2. Charlie-Gibbs Fracture Zone and Subpolar Frontal Zone of the Mid-Atlantic Ridge
ICES advises that an area with the following boundaries, capturing three distinct features, would meet one or more EBSA
criteria. The area would include the following features:
iii.
iv.
v.
Subpolar Frontal Zone (coinciding with the Charlie-Gibbs Fracture Zone): The northern and southern
boundaries for this feature should be set according to the known northernmost and southernmost meandering of
the frontal system at 53°N and 48°N, respectively (Søiland et al., 2008). The eastern and western boundaries for
this feature should be set according to the eastern and westernmost extension of the Charlie-Gibbs Fracture Zone
(topography; approx. at 27°W and 42°W, respectively).
Charlie-Gibbs Fracture Zone: The eastern and western boundaries for this feature should be set according to the
east–west extension of the Fracture Zone (approx. at 27°W and 42°W, respectively). The northern and southern
boundaries for this feature should be set with a view to encompass the characteristic bathymetry, topography,
and substrates of the Fracture Zone.
Sections of the Mid-Atlantic Ridge: The northernmost and southernmost boundaries would coincide respectively
with the southern boundary of proposed Area 1 (Reykjanes Ridge south of Iceland EEZ) and the northern
boundary of proposed Area 3 (Mid-Atlantic Ridge north of the Azores). Boundaries to the east and to the west
would be a depth contour running in the deeper of two properties:
•
•
including a large portion (arbitrarily, perhaps 90%) of all hard volcanic substrates; habitats reported to
host the larger known coral deposits and their associated communities;
including a large portion (arbitrarily, 90%) of the larger known deep-sea sponge aggregations.
Where the Charlie-Gibbs Fracture Zone crosses the Mid-Atlantic Ridge, the benthic boundaries of the Fracture Zone in
feature ii) may extend to the east and west beyond the area defined by feature iii) for the Mid-Atlantic Ridge. In those
cases the benthic area of the Fracture Zone is proposed for inclusion in the EBSA proposed here. However, any part of
the seafloor and associated benthos that lies below the pelagic feature i) (the total area occupied by the Subpolar Front
during its annual movement) but does not meet either feature ii) or feature iii) is not included in the area proposed as
meeting EBSA criteria. Only those parts of the water column where the Subpolar Front is prominent at some time during
the year are proposed as meeting one or more of the EBSA criteria. Moreover, in the entire pelagic area described by i),
at any given time only those parts of the total area where the Subpolar Front is located would be expected to meet some
of the criteria. Although maps will show the full pelagic area is proposed as part of this complex EBSA, any conservation
measures for ecological properties of the water column would need to take into account the position of the Subpolar Front
to be fully effective. For each of the above-mentioned features a set of geographic coordinates delineating their respective
boundaries needs to be determined.
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ICES Advice 2013, Book 1
Evaluation of the revised area against the EBSA criteria
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t Know
The area contains either (i) unique
(“the only one of its kind”), rare
(occurs only in few locations), or
endemic species, populations, or
communities, and/or (ii) unique,
rare, or distinct habitats or
ecosystems, and/or (iii) unique or
unusual
geomorphological
or
oceanographic features.
Explanation for ranking
Uniqueness
rarity
or
Low
Some
X
High
(X)
The portion of the proposed area encompassing both the Charlie-Gibbs Fracture Zone and Subpolar Front Zone are
unique. Both represent unique or unusual geomorphological or oceanographic features in the Northeast Atlantic. Other
portions of the proposed EBSA are part of the Mid-Atlantic Ridge and, as discussed for Area 1 (Reykjanes Ridge south
of Iceland EEZ), may host some unique benthic species based on Mar-Eco sampling.
Areas that are required for a
Special
X
importance for population to survive and thrive.
life-history
stages of species
Explanation for ranking
There is no evidence available suggesting a significant importance of the area for life-history stages of widespread
species in comparison to other marine areas of similar size and depth range.
Importance for Areas containing habitats for the
X
survival
and
recovery
of
threatened,
endangered, or endangered, threatened, or declining
species, or areas with significant
declining
species and/or assemblages of such species.
habitats
Explanation for ranking
There is good evidence that the area contains a significant assemblage of species and habitats that are assessed to be
threatened, endangered, or declining, including the following: orange roughy (Hoplostethus atlanticus), leafscale
gulper shark (Centrophorus squamosus), gulper shark (Centrophorus granulosus), Portuguese dogfish (Centroscymnus
coelepis), Sei whale (Balaenoptera borealis), sperm whale (Physeter macrocephalus), leatherback turtle (Dermochelys
coriacea), Lophelia pertusa reefs, and deep-sea sponge aggregations. Depending on the species, the special features
of the Fracture Zone, the Subpolar Frontal Zone, or in a few cases the Mid-Atlantic Ridge, all provide important
biological functions to the species which aggregate along each one.
Areas that contain a relatively high
Vulnerability,
X
proportion of sensitive habitats,
fragility,
sensitivity, or biotopes, or species that are
functionally
fragile
(highly
slow recovery
susceptible to degradation or
depletion by human activity or by
natural events) or with slow
recovery.
Explanation for ranking
The Charlie-Gibbs Fracture Zone and sections of the Mid-Atlantic Ridge through its associated substrate, current, and
feeding conditions, provide habitats to a number of sensitive/vulnerable species and communities both on soft and hard
substrate and in the water column. In particular biogenic habitats such as those formed by cold-water corals and sponges
are considered vulnerable, often fragile, and slow (if at all) to recover from damage. Some fish species associated with
the Fracture Zone and Mid-Atlantic Ridge also show slow growth, late maturity, irregular reproduction, and long
generation time, as well as community characteristics of high diversity at low biomass. However, there is no evidence
available suggesting that the area contains a significantly higher proportion of species that are functionally fragile or
with slow recovery than other areas of comparable structure and depth range along the Mid-Atlantic Ridge.
ICES Advice 2013, Book 1
239
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t Know
Areas
containing
species,
populations, or communities with
comparatively
higher
natural
biological productivity.
Explanation for ranking
Biological
productivity
Low
X
Some
High
(X)
There is good evidence that, due to the Subpolar Front, the pelagic area where the front is located at any particular time
is characterized by an elevated abundance and diversity of many taxa, including an elevated standing stock of
phytoplankton. This justifies a ranking of “High” for the pelagic area around the Subpolar Front, as it moves seasonally.
However, there is no evidence of relatively elevated productivity in the benthic communities of the Fracture Zone and
Mid-Atlantic Ridge.
Areas containing a comparatively
Biological
X
(X)
higher diversity of ecosystems,
diversity
habitats, communities, or species, or
with higher genetic diversity.
Explanation for ranking
The area of the Fracture Zone is characterized by a very high structural complexity, offering a diverse range of habitats.
The area of the Subpolar Front is a feature where species are documented to assemble seasonally, and the sections of
the Mid-Atlantic Ridge north and south of the Fracture Zone represent different biogeographic settings and their
respective characteristic communities. Consequently, each of the three features characterizing this area contribute to a
relatively higher diversity of ecosystems, habitats, communities, and species in comparison to other areas of similar
size along the Mid-Atlantic Ridge.
Area 3. Mid-Atlantic Ridge north of the Azores
ICES considers that one or more EBSA criteria would be met by an area with boundaries including all the following
properties:
•
•
•
240
Including a large portion (arbitrarily, perhaps 90%) of all hard volcanic substrates on the Mid-Atlantic Ridge
south of the summer location of the Subpolar Front.
Including the Moytirra Hydrothermal Vent Field.
Incluings the area in the Mid-Atlantic Ridge included in the 50% density Kernel for foraging Cory’s shearwater.
ICES Advice 2013, Book 1
Evaluation of the proposed area against the EBSA criteria
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Know
The area contains either (i) unique
(“the only one of its kind”), rare
(occurs only in few locations), or
endemic species, populations, or
communities, and/or (ii) unique,
rare, or distinct habitats or
ecosystems, and/or (iii) unique or
unusual
geomorphological
or
oceanographic features.
Explanation for ranking
Uniqueness
rarity
or
Low
X
Some
High
(X)
There is support for qualification under this criterion only from the hydrothermal vent field in the area which is
considered to be rare, and its associated communities which may be unique. This habitat is known from a single discrete
location (thus the brackets) and so it cannot be considered to offer justification for the entire extent of the proposed
area. ICES does not consider that any of the other evidence presented here supports qualification under this criterion.
Areas that are required for a
Special
X
importance for population to survive and thrive.
life-history
stages of species
Explanation for ranking
There is some support for qualification under this criterion from the occurrence of an important long-range foraging
area for Cory’s shearwaters during their breeding season. However, the core area encompassing 50% of locations at
sea is relatively small and does not justify the entire extent of the proposed area.
If research finds that deep-sea sharks and rays use the denser coral deposits as important spawning and nursery grounds,
as has been reported in the Hatton–Rockall Bank area proposed by ICES, then there would be additional justification
for a score of “Some” on this criterion.
Importance for Areas containing habitats for the survival and
X
recovery of endangered, threatened, or declining
threatened,
endangered, or species, or areas with significant assemblages of
such species.
declining
species and/or
habitats
Explanation for ranking
The only recognised threatened and/or declining species identified in the report as occurring in the area are the deepwater sharks Centrophorus squamosus and Centroscymnus coelolepis, both of which are included on the OSPAR list
of threatened and/or declining species and habitats. Since this area is not considered to have special importance for
their survival (compared with other areas of similar depth and latitude elsewhere) they would not qualify under this
criterion.
However, in addition to the threatened and declining species mentioned in the proposal, the OSPAR listed habitats
‘seamount communities’ and ‘coral gardens’ are likely to exist in this area. If these were taken into account together
with the sharks, this might be regarded as a significant assemblage of threatened and declining species and habitats
and the ranking would be “Some”.
Areas that contain a relatively high proportion of
Vulnerability,
X
sensitive habitats, biotopes, or species that are
fragility,
sensitivity, or functionally fragile (highly susceptible to
degradation or depletion by human activity or by
slow recovery
natural events) or with slow recovery.
Explanation for ranking
The proposed area focuses on areas with high abundance of seamounts, stony corals, and coral gardens. Recently a
new hydrothermal vent was discovered on the ridge at 45ºN. Seamounts, ocean ridges with hydrothermal vents, coral
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241
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
High
Know
reefs, and coral gardens are all considered priority habitats in need of protection by the OSPAR convention for the
protection and conservation of the Northeast Atlantic.
There is good support for qualification under this criterion from the occurrence of vulnerable marine ecosystems,
including seamounts, stony corals, coral gardens, and hydrothermal vents.
Areas containing species, populations, or
Biological
X
communities with comparatively higher natural
productivity
biological productivity.
Explanation for ranking
There is no evidence that the productivity in the revised area is any different from the expected productivity of marine
systems of similar depth and latitude.
Areas containing a comparatively higher diversity of
Biological
X
ecosystems, habitats, communities, or species, or
diversity
with higher genetic diversity.
Explanation for ranking
The presence of a hydrothermal vent field does not in itself indicate high diversity, but it does provide some evidence
of habitat heterogeneity from which species diversity may be inferred. In addition, there is a mingling of benthic
faunas characteristic of both warmer southern and cooler northern ocean environments, giving the area as a whole
somewhat higher net biological diversity, although the diversity in any individual site is not markedly enhanced.
Area 4. The Hatton and Rockall banks and the Hatton–Rockall Basin
The Hatton and Rockall banks, and associated slopes, represent unique offshore bathyal habitats (200 to 3000 m) and
constitute a prominent feature of the Northeast Atlantic continental margin south of the Greenland to Scotland ridges.
The banks and slopes have high habitat heterogeneity and support a wide range of benthic and pelagic faunas. They are
also subject to significant fishing impact, including bottom trawling, longlining, and midwater fisheries. The banks
encompass a large depth range and consequently the seabed communities encounter strong environmental gradients (e.g.
temperature, pressure, and food availability). These factors cause large-scale changes in species composition with depth
and give rise to a high diversity of species and habitats. The area is influenced by a number of different water masses and
there is considerable interaction between the topography and physical oceanographic processes, in some areas focusing
internal wave and tidal energy which results in strong currents and greater mixing and resuspension.
ICES recommend that additional work is needed primarily to refine the boundaries set out for this proposed EBSA. In
particular the evidence base to use the 3000 m contour as the southern and western limits of this proposed EBSA is
questionable since no evidence was provided that ecosystems meeting EBSA criteria are present at these depths. The
features contributing to the uniqueness and rarity, threatened and declining species, vulnerability/fragility/sensitivity, and
importance for life-history criteria stages all occur exclusively at relatively shallow depths (< 1500 m) with most being <
1200 m, and the only additional benefit gained by extending the boundary to 3000 m is an increase in the overall depth
range covered and hence additional biological diversity. It is unclear whether the additional diversity conferred by the
inclusion of the 1500 to 3000 m depth zone is any different from that present in any other area at comparable depth and
latitude.
ICES therefore recommends that proposed EBSA should go forward with a revised boundary approximating to the 1500
m depth contour. If further work can establish significant additional value in the inclusion of greater depths, the boundary
could be adjusted accordingly in the future.
Evaluation of the proposed area against the EBSA criteria
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Know
Uniqueness
rarity
242
or
The area contains either (i) unique (“the only one
of its kind”), rare (occurs only in few locations), or
endemic species, populations, or communities,
Low
Some
High
X
(X)
ICES Advice 2013, Book 1
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Know
Low
Some
High
and/or (ii) unique, rare, or distinct habitats or
ecosystems, and/or (iii) unique or unusual
geomorphological or oceanographic features.
Explanation for ranking
The area has considerable environmental heterogeneity, and therefore biological diversity, as a result of its large depth
range and strong environmental gradients. Habitat-forming sessile benthic communities, such as those of giant
protozoans and sponges, are common. Although distinctive these features are not rare per se.
Large areas of cold-water corals and sponges have been reported in the area. Some of these have been impacted by
bottom trawl and longline fishing and past periods of bottom gillnet fishing, but some areas of large coral frameworks
still exist, including areas such as the Logachev coral carbonate mound province which spans both national EEZ
(Ireland) and international waters. Many of these coral frameworks are now protected as VMEs.
An area of polygonal faults may be a unique seabed feature. It is currently poorly investigated but may host important
biological communities (e.g. cold-seeps).
The polygonal faults do not themselves appear to support unique biological communities or species but may be
indicative of possible presence of active hydrocarbon seeps. One such active seep has recently been discovered in this
area, supporting a rare chemosynthetic community that hosts species that have not been recorded elsewhere (hence the
bracketed “High” score).
There is support for qualification under this criterion from the occurrence of polygonal faults and an active cold
hydrocarbon seep. These features exist within a very restricted area of the site and, as described, the uniqueness and
rarity criterion would only apply where these habitats occur. If further information is provided on the occurrence of
large areas of cold-water coral reef, this may provide further support for this criterion over a wider geographical area.
Areas that are required for a population to survive
Special
X
importance for and thrive.
life-history
stages of species
Explanation for ranking
Cold-water corals and areas of natural coral rubble provide highly diverse habitats. Recent observations show that
Lophelia pertusa reefs provide nursery grounds for deep-water sharks, and egg cases of deep-water rays were recorded
with small patches of Solenosmilia variabilis framework on the Hebrides Terrace Seamount during the RRS James
Cook 073 Changing Oceans Expedition in June 2012. New evidence from RRS James Cook cruises 073 and 060 shows
that small patch reefs of L. pertusa on Rockall Bank are used as refuge by gravid Sebastes viviparous.
Parts of the Hatton–Rockall area are important as spawning areas for blue whiting, and the area is used as a corridor
for a range of migrating species, including turtles.
Blue whiting has a widespread spawning area from the Faroe–Shetland Channel in the north to the Porcupine Bank in
the south. Three areas of blue ling spawning aggregations are known on the shallow parts of Hatton and Lousy banks.
These are significant since they represent three of the six known or suspected spawning locations for the southern stock
of blue ling.
Importance for Areas containing habitats for the survival and
X
recovery of endangered, threatened, or declining
threatened,
endangered, or species, or areas with significant assemblages of
such species.
declining
species and/or
habitats
Explanation for ranking
The OSPAR threatened and declining habitats and species “carbonate mounds” and Lophelia pertusa are confirmed to
be present in the area, and indicator species for “deep-sea sponge aggregations” and “coral gardens” have been recorded.
The presence of these habitats has been confirmed in some areas that are now protected as VMEs.
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CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
High
Know
The cold-water corals and natural rubble contain very large numbers of invertebrate species, including giant protozoans
(xenophyophores), vase-shaped white sponges, actiniarians, antipatharian corals, hydroids, bryozoans, asteroids,
ophiuroids, echinoids, holothurians, and crustaceans.
The distribution of cold-water coral has been severely reduced in the area over the last 30 years.
The deep-water sharks C. coelolepis and C. squamosus are also listed in the OSPAR list. Both occur in the area, but
there is no information to indicate that this area is important for either species in the sense of having a significant
proportion of the population or higher density than other areas of similar depth in the region.
Both Zino’s petrel (endangered) and Fea’s petrel (near threatened) are listed on the IUCN Red List. A further five
species of seabirds listed in Annex I of the European Union Bird’s Directive are found within the area. However,
tracking for the two petrel species (data in Figure 2 of the proposal; OSPAR/NEAFC/CBD, 2011) appears to show that
the area is of relatively low importance (5 to 10% of tracked birds) during a very short period (one month).
Knowledge of cetaceans in the area is poor, but the critically endangered northern right whale (Eubalaena glacialis)
has been observed in this area. However, this single observation is insufficient to demonstrate importance for this
species.
Areas that contain a relatively high proportion of
Vulnerability,
X
sensitive habitats, biotopes, or species that are
fragility,
sensitivity, or functionally fragile (highly susceptible to
degradation or depletion by human activity or by
slow recovery
natural events) or with slow recovery.
Explanation for ranking
It is uncertain how “a relatively high proportion” is defined in this context, but there is good evidence for vulnerable
habitats and benthic species in the area (records of cold-water coral reefs and carbonate mounds, and indicator species
for coral gardens, deep-water sponge aggregations). Distribution is not uniform across the area and many of the areas
where they occur are now protected as VMEs.
There is a high diversity of corals, including bamboo coral (Isididae), black coral (Antipatharia), as well as the reefforming stony corals (Scleractinia), though some of these may now be reduced in distribution and occurring in patches.
Cold-water coral habitats are easily impacted and recover very slowly. Some species of cold-water corals can live for
more than 4000 years.
Many of the demersal fish have life histories of deep-water fish fauna with very slow recovery times as a result of their
slow reproductive rate compared to pelagic fish. These fish may be more exposed to fishing pressure because trawlable
habitat is more common in this area than is typical at these depths. Stocks have already been diminished in some areas.
There is good support for qualification under this criterion from the occurrence of vulnerable marine ecosystems,
including stony corals, carbonate mounds, possible coral gardens and deep-sea sponge aggregations, and an active cold
seep. Although comparative studies have not been done, it is probable that occurrence of corals in the Rockall–Hatton
area is higher than in other areas of comparable depth and latitude. This would therefore constitute a “relatively high
proportion”.
The species or habitats discussed in this rationale are generally found in depths above 1500 m and thus this proposed
EBSA should be limited to this depth contour.
Areas containing species, populations, or
Biological
X
communities with comparatively higher natural
productivity
biological productivity.
Explanation for ranking
It is likely that pelagic production may be enhanced relative to surrounding areas due to upwelling, but benthic
secondary production in deep-water environments is generally considered to be low compared to other environments.
Areas containing a comparatively higher diversity
Biological
X
of ecosystems, habitats, communities, or species,
diversity
or with higher genetic diversity.
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CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Know
Low
Some
High
Explanation for ranking
The area comprises a patchwork of habitats with species changing consistently with both habitat type and increasing
depth. Some habitats are threatened by direct impacts (e.g. bottom fishing), others may suffer indirectly (e.g. through
the creation of sediment plumes by impacts of fishing gear in sensitive areas). Seabed communities include cold-water
corals, rocky reefs, carbonate mounds, polygonal fault systems, sponge aggregations, and steep and gentle sedimented
slopes. Cold-water corals provide diverse habitats for other invertebrates and fish.
This area spans more than one biogeography province; consequently, overall diversity is likely to be higher than in
other areas with comparable depth and habitat range. Rare habitats such as cold seeps and highly diverse habitats such
as cold-water coral reef and rubble further contribute to the overall diversity.
Proposal for a different configuration of EBSAs than those presented in the OSPAR/NEAFC/CBD Workshop
report
Proposed EBSAs 1, 2, and 3 (Reykjanes Ridge south of Iceland EEZ, Charlie-Gibbs Fracture Zone and Subpolar Frontal
Zone of the Mid-Atlantic Ridge, and Mid-Atlantic Ridge north of the Azores) all encompass the hard substrates running
roughly north–south in the higher elevations of the Mid-Atlantic Ridge, and for proposed EBSAs 1 to 3 the southern
boundary of each aligns with the northern boundary of the next. The boundaries between them were defined primarily by
the extreme limits of the position of the east–west-oriented Subpolar Front, a major pelagic oceanographic feature in
proposed EBSA 2 that moves seasonally northward spring and summer) and southward (autumn and winter).
The Subpolar Front has affinities with the Charlie-Gibbs Fracture Zone, but not with the Mid-Atlantic Ridge. If the
Charlie-Gibbs Fracture Zone, running roughly east to west, and associated Subpolar Frontal Zone were treated separately
from the Mid-Atlantic Ridge, then all the areas delineated by the features of the Mid-Atlantic Ridge specified for the
proposed EBSAs 1, 2, and 3 would share a consistent geomorphological feature (the emergent hard substrates primarily
of volcanic origin) with associated benthic fauna present from the northern boundary of proposed EBSA 1 to the southern
boundary of proposed EBSA 3, with the Charlie-Gibbs Fracture Zone itself simply serving as an interruption in this
feature.
The entire Mid-Atlantic Ridge feature would score “Some” or “High” on several criteria, and for generally the same
biological rationales for the entire ridge. The species composition of the benthic biota does change from north to south,
but aside from the structural interruption caused by the transverse fractures, there is no strong evidence that discontinuities
in benthic community composition exist along the ridge. Thus, an alternative area to proposed EBSAs 1, 2, and 3 can be
justified along the entire Mid-Atlantic Ridge in the OSPAR/NEAFC area, defined by the features specified in the
description of proposed EBSA 1, and ranked as “Some” or “High” on several EBSA criteria with a common justification
for that entire area.
A second alternative EBSA could then be proposed, consisting of the Charlie-Gibbs Fracture Zone and Subpolar Frontal
Zone, taken together. This area would have its own set of ecological properties and associated rankings on the EBSA
criteria. It would be ranked “Some” or “High” on several criteria for justifications specific to the Fracture Zone and
Subpolar Front, but in several cases for justifications very different from that of the Mid-Atlantic Ridge.
These two potential proposed EBSAs would replace proposed EBSAs 1, 2, and 3 from the OSPAR/NEAFC/CBD
Workshop report. It would also require a separate consideration of seabird foraging in the southern third of the area,
jointly with the additional analyses already recommended for the OSPAR/NEAFC/CBD Workshop proposed EBSAs 5–
8.
Alternative proposed EBSA for the Mid-Atlantic Ridge
The Mid-Atlantic Ridge runs from the southern boundary of the Icelandic EEZ to the northern boundary of the Portuguese
EEZ in the Azores and includes all area above a depth contour that runs in the deeper of two properties:
5.
6.
Including a large portion (arbitrarily, perhaps 90%) of all hard volcanic substrates; habitats are reported to host
the larger known coral deposits and their associated communities.
Included a large portion (arbitrarily, 90%) of the records of large sponge communities in the overall Mid-Atlantic
Ridge.
ICES Advice 2013, Book 1
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In addition the proposed area should include all known hydrothermal vents along the ridge, if any of these are deeper than
the contours meeting the properties above.
Evaluation of the proposed area against the EBSA criteria
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
High
Know
The area contains either (i) unique (“the only one of
X
(X)
its kind”), rare (occurs only in few locations), or
endemic species, populations, or communities,
and/or (ii) unique, rare, or distinct habitats or
ecosystems, and/or (iii) unique or unusual
geomorphological or oceanographic features.
Explanation for ranking
The qualified “High” ranking is for restricted areas of the few known hydrothermal vents along the ridge. These are
globally rare features; only a small part of the area proposed here meets this EBSA criterion.
Uniqueness
rarity
or
The MarEco sampling of corals and sponges reported several species new to science as it sampled the Mid-Atlantic
Ridge. However, it is not possible to draw a firm conclusion on the presence of unique species along the ridge until
more extensive sampling is undertaken.
Areas that are required for a population to survive
Special
X
importance for and thrive.
life-history
stages of species
Explanation for ranking
Although many populations undoubtedly complete their life cycles within the harder-substrate areas of the MidAtlantic Ridge, this would be true of any marine area of comparable size. There is no evidence that the life history of
any species is strongly dependent on any specific features of the area proposed as an alternative EBSA.
There is evidence from other areas of the Northeast Atlantic that areas of high coral density may be important as eggcase and nursery areas of deep-water sharks and rays. The area proposed here is targeted on the depths and substrates
associated with higher coral and sponge densities, and if sharks and rays also concentrate spawning and early
development in these habitats, then the score would be “Some” or “High” on this criterion as well. However, it has not
yet been documented that skates and rays do preferentially use the coral and sponge formations for these life history
functions in the Mid-Atlantic Ridge.
For the more southern portions of the Mid-Atlantic Ridge in particular, there are reports of areas being important for
foraging by seabirds, including Cory’s shearwater. The evidence available is not considered strong, however, and this
aspect of the ecological functionality of the central ridge area should be considered as part of the reanalysis of EBSAs
5–8 proposed in the OSPAR/NEAFC/CBD Workshop report.
Importance for Areas containing habitats for the survival and
X
recovery of endangered, threatened, or declining
threatened,
endangered, or species, or areas with significant assemblages of
such species.
declining
species and/or
habitats
Explanation for ranking
There are large deposits of corals and sponges found in the alternative area proposed by ICES as meeting this criterion.
Habitats containing these species are listed by OSPAR and are also VME indicator species, and the majority of these
would be included in the alternative proposed EBSA. Additional explanation regarding corals and sponges is included
in the rationale for the criterion on Vulnerability.
The possible role of the alternative proposed Mid-Atlantic Ridge area in the life histories of sharks and rays is discussed
in the criterion on Vulnerability and Sensitivity. If a dependency between the breeding or early life history of threatened
or endangered skates or rays were documented, there would be additional justification for a “High” ranking of this
criterion.
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CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
High
Know
Areas that contain a relatively high proportion of
sensitive habitats, biotopes, or species that are
functionally fragile (highly susceptible to
degradation or depletion by human activity or by
natural events) or with slow recovery.
Explanation for ranking
Vulnerability,
fragility,
sensitivity, or
slow recovery
X
With regard to corals and sponges, Mortensen et al. (2008) found cold-water corals “at every sample station …
observed at depths between 800 and 2400 m, however were commonly found shallower than 1400 m …, with species
richness being very high. … no major reef structures were recorded, with the maximum colony size approximately 0.5
m in diameter. The number of coral taxa was strongly correlated with the percentage cover of hard bottom substrate
….” The area proposed here is targeted at the seamount peaks and slopes where hard substrates dominate. For sponges,
no actual large expanses of sponge reef were reported in the OSPAR/NEAFC/CBD Workshop report. However, the
pro forma in that report notes that overall sampling of the area is patchy and cites three studies that found local patches
with high densities of sponges, although in no cases were the sizes of the patches documented.
If research finds that deep-sea sharks and rays use the denser coral deposits as important spawning and nursery grounds,
as has been reported in the Hatton–Rockall Bank area proposed by ICES, then there would be additional justification
for a score of “Some” on this criterion.
Areas containing species, populations, or
Biological
X
communities with comparatively higher natural
productivity
biological productivity.
Explanation for ranking
Although benthic productivity of the alternative proposed Mid-Atlantic Ridge EBSA may be higher than benthic
productivity on the abyssal plain, productivity integrated over the entire water column and seafloor seems typical of
systems of comparable depth and latitude globally.
Areas containing comparatively higher diversity of
Biological
X
ecosystems, habitats, communities, or species, or
diversity
with higher genetic diversity.
Explanation for ranking
The presence of comparatively large coral and sponge formations, and the documented high diversity of benthic and
associated fish when corals or sponges are present in moderate or high density imply that some areas along the ridge
may have high diversity. From north to south there is a mingling of benthic and demersal fish faunas characteristic of
both cooler northern and warmer southern ocean environments, giving the area as a whole a somewhat higher net
biological diversity, even if the diversity in any individual site is not markedly enhanced. Aside from the benthic
communities of somewhat restricted distribution associated with the biogenic habitats, the biodiversity otherwise
appears typical of biotic communities at similar depths and latitude.
Alternative proposed EBSA – The Charlie-Gibbs Fracture Zone and Subpolar Frontal Zone
The area would include:
vi.
vii.
Subpolar Frontal Zone (coinciding with the Charlie-Gibbs Fracture Zone): The northern and southern
boundaries for this feature should be set according to the known northernmost and southernmost locations of the
frontal system (at approximately 53°N and 48°N). The eastern and western boundaries for this feature should be
set according to the eastern and westernmost extension of the Charlie-Gibbs Fracture Zone (at approximately
27°W and 42°W).
Charlie-Gibbs Fracture Zone: The eastern and western boundaries for this feature should be set according to the
east–west extension of the Fracture Zone (at approximately 27°W and 42°W). The northern and southern seabed
boundaries for this feature should be set with a view to encompass the characteristic topography and substrates
of the Fracture Zone.
Any area of the seafloor and associated benthos that lies below the pelagic feature i) (the total area occupied by the
Subpolar Front during its annual movement) but does not meet feature ii) is not included in the area proposed as meeting
EBSA criteria. Only those parts of the water column where the Subpolar Front is prominent at some time during the year
are proposed as meeting one or more of the EBSA criteria. Moreover, in the entire pelagic area described by i), at any
ICES Advice 2013, Book 1
247
given time only that part of the total area where the Subpolar Front is located would be expected to meet some of the
criteria. Although maps will show that the full pelagic area is proposed as part of this complex EBSA, any conservation
measures for ecological properties of the water column would need to take into account the position of the Subpolar Front
to be fully effective.
Evaluation of the proposed area against the EBSA criteria
CBD
EBSA
Criterion
Description
The area contains either (i) unique (“the only one of
its kind”), rare (occurs only in few locations), or
endemic species, populations, or communities,
and/or (ii) unique, rare, or distinct habitats or
ecosystems, and/or (iii) unique or unusual
geomorphological or oceanographic features.
Explanation for ranking
Uniqueness
rarity
or
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
High
Know
X
The Charlie-Gibbs Fracture Zone is a set of geomorphological features unique to the entire North Atlantic, and the
Subpolar Front is an oceanographic feature also unique to the Northeast Atlantic. Together these features justify a
“High” score for this criterion.
Areas that are required for a population to survive
Special
X
importance for and thrive.
life-history
stages of species
Explanation for ranking
No evidence is available suggesting a significant importance of the area for life-history stages of widespread species
in comparison with other marine areas of similar size and depth range. It is possible that there are species with special
affinities for the unique geophysical features of the deep faults, but clear documentation of species with such affinities
was not found in the references provided by the OSPAR/NEAFC/CBD Workshop report, and was not otherwise known
to ICES.
Importance for Areas containing habitats for the survival and
X
recovery of endangered, threatened, or declining
threatened,
endangered or species, or areas with significant assemblages of
such species.
declining
species and/or
habitats
Explanation for ranking
There is good evidence that the area contains a significant assemblage of species and habitats that are assessed to be
threatened, endangered, or declining, including leafscale gulper shark (Centrophorus squamosus), gulper shark
(Centrophorus granulosus), Portuguese dogfish (Centroscymnus coelepis), Sei whale (Balaenoptera borealis), sperm
whale (Physeter macrocephalus), leatherback turtle (Dermochelys coriacea), as well as cold-water coral reefs and
deep-sea sponge aggregations. Depending on the species, the special features of the Fracture Zone and the Subpolar
Front are inferred to provide important biological functions to the species which aggregate along each one.
Areas that contain a relatively high proportion of
Vulnerability,
X
sensitive habitats, biotopes, or species that are
fragility,
sensitivity, or functionally fragile (highly susceptible to
degradation or depletion by human activity or by
slow recovery
natural events) or with slow recovery.
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CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
High
Know
Explanation for ranking
The Charlie-Gibbs Fracture Zone geophysical structure provides habitats for a number of sensitive/vulnerable species
and communities both on soft and hard substrate and in the associated water column. In particular biogenic habitats
such as those formed by cold-water corals and sponges are considered vulnerable, are often fragile, and slow (if at all)
to recover from damage. Some fish species associated with the Fracture Zone and the Subpolar Front also show slow
growth, late maturity, irregular reproduction, and long generation time, as well as community characteristics of high
diversity at low biomass. However, the documentation that the species with vulnerable life histories are especially
closely affiliated with the Fracture Zone and frontal habitats is weak, and it is clear that these vulnerable species and
biogenic habitats are not consistently present throughout the entire Fracture Zone and Subpolar Front.
Areas containing species, populations, or
Biological
X
(X)
communities with comparatively higher natural
productivity
biological productivity.
Explanation for ranking
There is good evidence that, because of the Subpolar Front, the pelagic area where the front is located at any particular
time is characterized by an elevated abundance and diversity of many taxa, including an elevated standing stock of
phytoplankton. This justifies a ranking of “High” for the pelagic area around the Subpolar Front, as it moves seasonally.
However, there is no evidence of relatively elevated productivity in the benthic communities of the Fracture Zone.
Areas containing a comparatively higher diversity of
Biological
X
ecosystems, habitats, communities, or species, or
diversity
with higher genetic diversity.
Explanation for ranking
The area of the Fracture Zone is characterized by a very high structural complexity, offering a diverse range of habitats.
The area of the Subpolar Front is a feature where species are documented to assemble seasonally. Consequently, both
features characterizing this area contribute to a relatively higher diversity of ecosystems, habitats, communities, and
species in comparison to other areas of the Northeast Atlantic.
Proposed EBSAs for which there is insufficient scientific justification
For five of the ten areas proposed as meeting one or more EBSA criteria in the OSPAR/NEAFC/CBD Workshop report,
ICES concluded that there is insufficient scientific justification at this time to propose their delineated area, or any subset
of it, as meeting EBSA criteria. In all cases ICES recommends that additional information needs to be collated and
analysed, and a new evaluation be conducted when those results are available. ICES provides reasoning for its advice and
recommendations for further work in each of these areas below.
Area 5. Around the Pedro Nunes and Hugo de Lacerda seamounts and
Area 6. Northeast Azores–Biscay Rise
The OSPAR/NEAFC/CBD Workshop concluded that both areas ranked as “High” on criterion Special Importance to Life
History of Species, and “Some” on criteria Uniqueness and Rarity; Importance to Threatened, Endangered, or Declining
Species; and Vulnerability, Sensitivity, etc., the latter primarily for seabirds. ICES questions the basis for these
conclusions, noting that the data used to assess all the criteria specified were incomplete and often incorrectly interpreted,
with the proposed boundaries not matching the information in the cited sources.
ICES recommends that all available data on foraging activity of the Zino’s petrel, Cory’s shearwater, and other relevant
species be examined. This should include published and any other available data. Occurrence data may be used as well,
provided the rationale details how occurrence and foraging data are used to derive EBSA boundaries.
Area 7. Evlanov Seamount region
The OSPAR/NEAFC/CBD Workshop concluded that the area they delineated ranked as “High” on criterion Importance
to Threatened, Endangered, or Declining Species, and “Some” on criteria Uniqueness and Rarity; Special Importance to
Life History of Species; and Vulnerability, Sensitivity, etc., the latter primarily for seabirds. ICES questions the basis for
these conclusions, noting that the data used to assess all the criteria specified were incomplete and often incorrectly
interpreted, with the proposed boundaries not matching the information in the cited sources. In particular the sample sizes
ICES Advice 2013, Book 1
249
for Fea’s petrel were very small, and the information for sooty shearwater did not seem to differentiate the proposed
EBSA area from most of surrounding area.
ICES advises not to proceed with proposing any portion of this area as an EBSA at this time, but rather undertake further
collation and analysis of information and reconsider when the additional work is completed.
Area 8. Northwest of Azores EEZ
The OSPAR/NEAFC/CBD Workshop concluded that the area they delineated ranked as “High” on criteria Special
Importance for Life History of Stages of Species and Importance for Threatened, Endangered or Declining Species, and
“Some” on criteria Uniqueness and Rarity; Vulnerability, Sensitivity, etc.; and Biological Diversity, the latter primarily
for seabirds. ICES questions the basis for these conclusions, noting that the data used to assess all the criteria specified
were incomplete and often incorrectly interpreted, with very small sample sizes for some of the species’ (e.g. Zino’s
petrel) foraging areas, and questionable interpretation of the foraging areas of Cory’s shearwater.
ICES does not support this area going forward as presented in the OSPAR/NEAFC/CBD EBSA Workshop report. ICES
advises that improvements are needed to the supporting evidence in the narrative for criteria related to Special Importance
for Life History Stages of Species and Importance for Threatened, Endangered or Declining Species and/or Habitats. It
is necessary to augment information on how the area is being used (feeding, conditioning, migration) for the survival and
recovery of the species and to put some scale on its importance to the species (some of which have very restricted breeding
sites in the larger area). It is also necessary to document the proportion of species that are highly susceptible to degradation
or depletion by human activity, in this case bycatch in longline fisheries.
Area 9. The Arctic Front – Greenland/Norwegian seas
The OSPAR/NEAFC/CBD Workshop concluded that the area they delineated ranked as “High” on criteria Special
Importance to Life History of Species; Importance to Threatened, Endangered, or Declining Species; Biological
Productivity; and Biological Diversity. ICES questions the basis for these conclusions, noting that (1) for several features
the area proposed as meeting criteria were not noticeably different from the surrounding areas; (2) some of the rankings
regarding importance appeared to be inferred from a belief that the area is high in productivity, but the rankings were not
demonstrated otherwise; and (3) publications with contrasting conclusions were found for some of the key references
cited in the OSPAR/NEAFC/CBD Workshop report.
ICES recommends not to proceed with the proposed Arctic Front EBSA. There is no evidence of enhanced productivity
at the Arctic Front which is the main rationale used to justify the proposed EBSA. However, there seems to be
circumstantial evidence for an enhanced production that may attract feeding animals in the areas around and south of Jan
Mayen, including the Jan Mayen Front. If parts of this area are located in the high seas, further analyses should be
undertaken to determine if this area meets the EBSA criteria.
Sources
CBD. 2007. Expert Workshop on Ecological Criteria and Biogeographic Classification Systems for Marine Areas in Need
of Protection. 2–4 October 2007, Azores, Portugal. (http://www.cbd.int/doc/meetings/mar/ewsebm01/official/ewsebm-01-02-en.pdf).
CBD. 2008. CBD Decision IX/20 on Marine and Coastal Biodiversity. (http://www.cbd.int/doc/decisions/cop-09/cop-09dec-20-en.pdf).
CBD. 2009. Expert Workshop on Scientific and Technical Guidance on the Use of Biogeographic Classification Systems
and Identification of Marine Areas beyond National Jurisdiction in Need of Protection. 29 September–2 October
2009, Ottawa, Canada. (https://www.cbd.int/doc/meetings/sbstta/sbstta-14/information/sbstta-14-inf-04-en.pdf).
CBD.
2010.
CBD
Decision
X/29
on
Marine
and
Coastal
Biodiversity.
(https://www.cbd.int/decision/cop/default.shtml?id=12295).
German, C. R., and Parsons, L. M. 1998. Distributions of hydrothermal activity along the Mid-Atlantic Ridge: interplay
of magmatic and tectonic controls. Earth and Planetary Science Letters, 160: 327–341.
German, C. R., Briem, J., Chin, C., Danielsen, M., Holland, S., James, R., Jónsdottir, A., Ludford, E., Moser, C., Ólafsson,
J., Palmer, M. R., and Rudnicki, M. D. 1994. Hydrothermal activity on the Reykjanes Ridge: the Steinahóll ventfield at 63°06’N. Earth and Planetary Science Letters, 121: 647–654.
ICES. 2013a. Vulnerable deep-water habitats in the NEAFC Regulatory Area. In Report of ICES Advisory Committee,
2013, Section 1.5.5.1. ICES Advice, 2013, Book 1.
ICES. 2013b. Report of the Workshop to Review and Advise on EBSA Proposed Areas (WKEBSA), 27–31 May 2013,
Copenhagen, Denmark. In draft.
250
ICES Advice 2013, Book 1
Mironov, A., and Gebruk, A. 2007. Deep-sea benthos of the Reykjanes Ridge: biogeographic analysis of the fauna living
below 1000 m. Report on preliminary phase of the project patterns and processes of the ecosystems of the northern
Mid-Atlantic (Mar-Eco).
(http://www.mareco.no/sci/component_projects/epibenthos/deep-sea_benthos_of_the_reykjanes_ridge).
Mortensen, P. B., Buhl-Mortensen, L., Gebruk, A. V., and Krylova, E. M. 2008. Occurrence of deep-water corals on the
Mid-Atlantic Ridge based on Mar-Eco data. Deep-Sea Research, 55: 142–152.
Olafsson, J., et al. 1991. A sudden cruise off Iceland. RIDGE Events Newsletter, 2(2): 35–38.
OSPAR/NEAFC/CBD. 2011. Report of the Joint OSPAR/NEAFC/CBD Scientific Workshop on the Identification of
Ecologically or Biologically Significant Marine Areas (EBSAs) in the North-East Atlantic. 8–9 September 2011,
Hyères, France. Annex 11.
Søiland, H., Budgell, W. P., and Knutsen, Ø. 2008. The physical oceanographic conditions long the Mid-Atlantic Ridge
north of the Azores in June–July 2004. Deep-Sea Research II, 55: 29–44.
United Nations. 2004. UNGA Resolution 58/240.
(http://daccess-dds-ny.un.org/doc/UNDOC/GEN/N03/508/92/PDF/N0350892.pdf?OpenElement).
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Annex 1.5.6.5.1
Revised pro forma for the Arctic Ice habitat
Annex 1
Joint OSPAR/NEAFC/CBD Scientific Workshop on the Identification of Ecologically or Biologically
Significant Marine Areas (EBSAs) in the North-East Atlantic
Hyères (Port Cros), France: 8 – 9 September 2011
________________________________________
EBSA identification proforma for the North-East
Atlantic - 10
Title/Name of the area - The Arctic Ice habitat - multiyear ice, seasonal ice and marginal ice zone
Presented by WWF and reviewed by Participants at the Joint OSPAR/NEAFC/CBD Scientific Workshop on
the Identification of Ecologically or Biologically Significant Marine Areas in the North-East Atlantic
Contact: Sabine Christiansen [email protected]
Abstract
The permanently ice covered waters of the high Arctic provide a range of globally unique habitats associated
with the variety of ice conditions. Multi-year sea ice only exists in the Arctic and although the projections of
changing ice conditions due to climate change project a considerable loss of sea ice, in particular multiyear
ice, the Eurasian Central Arctic high seas are likely to at least keep the ice longer than many other regions in
the Arctic basin. Ice is a crucial habitat and source of particular foodweb dynamics, the loss of which will affect
also a number of mammalian and avian predatory species. The particularly pronounced physical changes of
Arctic ice conditions as already observed and expected for the coming decades, will require careful ecological
monitoring and eventually measures to maintain or restore the resilience of the Arctic populations to quickly
changing environmental conditions.
Introduction
Up until today most of the Eurasian part of the Arctic Basin, and in particular the high seas area in the Arctic
Ocean (the waters beyond the 200 nm zones of coastal states, i.e. Norway, Russia, USA, Canada and
Greenland/Denmark) is permanently ice covered. However, in recent years, much of the original multiyear
pack ice has been replaced by seasonal (1 year) ice which made it possible for research and other vessels to
reach the pole. In addition, the former fast pack-ice is now increasingly broken up by leads. This structural
change in the Arctic ice quality will result in a substantial increase in light penetrating the thin ice and water
column, in conjunction with the overall warming of surface waters and increased temperature and salinity
stratification due to the melting of ice.
In the near future, up to the end of the century, the permanent ice cover is expected to disappear completely
in some models (Anisimov et al., 2007). This will result in significant changes in the structure and dynamics of
the high Arctic ecosystems (CAFF, 2010; Gradinger, 1995; Piepenburg, 2005; Renaud et al., 2008;
Wassmann, 2008, 2011) which should be closely monitored (Bluhm et al., 2011) as already envisaged by the
Arctic Council (Gill et al., 2011; Mauritzen et al., 2011).
Therefore, the area proposed here as EBSA is of particular scientific interest and may in the longterm, become
relevant for the commercial exploitation of resources.
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Location
The Ecologically or Biologically Significant Marine Area (EBSA) proposed focusses on the presently
permanently ice-covered waters in the OSPAR/NEAFC maritime areas, including the high seas section in the
Central Arctic Basin north of the 200 nm zones of coastal states (see Fig. 1 attached). Therefore, the
boundaries proposed extend from the North Pole (northernmost point of OSPAR/NEAFC maritime areas) to
the southern limit of the summer sea ice extent and marginal ice zone, including on the shelf of East Greenland.
The proposal currently only relates to features of the water column. Two legal states have to be distinguished:
the Central Arctic high seas waters north of the 200 nm zones of adjacent coastal states, generally north of
84° N, and the waters within the Exclusive Economic Zones of Greenland, Russia and the fisheries protection
zone of Norway around Svalbard. Figure 1 distinguishes between the high seas beyond national jurisdiction
for which the „Joint OSPAR/NEAFC/CBD Scientific Workshop on the Identification of Ecologically or
Biologically Significant Marine Areas (EBSAs) in the North-East Atlantic“ has a mandate19, and
national/nationally administered waters within the 200 nm zone, within which the OSPAR Contracting Parties
have the responsiblity to report candidate EBSAs to the Convention on Biodiversity EBSA repository (OSPAR
Commission, 2011).
The seafloor of the respective region will likely fall on the extended continental shelves of several coastal
states. It belongs to the „Arctic Basin“ region of (Gill et al., 2011).
The coordinates of the overall area, as well as the high seas section are provided in Annex 1 (in decimals,
shape files provided):
c.f. Figure 1: Location of the Arctic Ice „Ecologically or Biologically Significant Area“ (EBSA) proposed by WWF
in September 2011. The position of the Arctic and polar fronts was redrawn after (Rey, 2004, Fig. 5.7).
Feature description
The Ecologically or Biologically Significant Marine Area (EBSA) proposed focusses on the presently
permanently ice-covered waters in the OSPAR/NEAFC maritime areas, including the high seas section in the
Central Arctic Basin north of the 200 nm zones of coastal states, and the marginal ice zone (where the ice
breaks up, also called seasonal ice zone) along its southern margins (see Fig. 1 attached). Due to the inflow
of Atlantic water along the shelf of Svalbard, and the concurrent outflow of polar water and ice on the Greenland
side of Fram Strait, the southern limit of the summer sea ice extent is much further south in the western
compared to the eastern Framstrait, and in former times extended all along the Greenland coast.
The high seas section of the OSPAR maritime area in the Central Arctic ocean is generally north of 84° N and
is until today fully ice-covered also in summer, although the quantity of multiyear ice has already substantially
decreased and the 1-year ice leaves increasingly large leads and open water spaces. The ice overlays a very
deep water body of up to 5000 m depth far away from the surrounding continental shelves and slopes of
Greenland and the Svalbard archipelago. The Nansen-Gakkel Ridge, a prolongation of the Mid-Atlantic Ridge
north of the Fram Strait is structuring the deep Arctic basin in this section, separating the Central Nansen Basin
to the south from the Amundsen Basin to the north. Abundant hydrothermal vent sites have been discovered
on this ridge at about 85° 38 N (Edmonds et al., 2003).
North of Spitsbergen, the Atlantic water of the West Spitsbergen Current enters the Arctic basin as a surface
current. At around 83° N, a deep-reaching frontal zone separates the incoming Atlantic and shelf waters from
those of the Central Nansen Basin (Anderson et al., 1989), as reflected in ice properties, nutrient
concentrations, zooplankton communities, and benthic assemblages (Hirche and Mumm, 1992, and literature
quoted). This water subsequently submerges under the less dense (less salinity, lower temperature) polar
water and circulates, in opposite direction to the surface waters and ice, counterclockwise along the continental
rises until turning south along the Lomonossov Ridge and through Fram Strait as East Greenland Current
south to Danmark Strait (Aagaard, 1989; Aagaard et al., 1985). Connecting the more fertile shelves with the
19 Participant Briefing for a Joint OSPAR/NEAFC/CBD Scientific Workshop on the Identification of Ecologically or
Biologically Significant Marine Areas (EBSAs) in the North-East Atlantic. Invitation Annex 2, 2011
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deep central basin, these modified Atlantic waters supply the waters north of the Nansen-Gakkel Ridge, in the
Amundsen basin, with advected organic material and nutrients which supplement the autochtonous production
(Mumm et al., 1998). Due to the import of organic biomass from the Greenland Sea and the Arctic continental
shelves, part of which may not be kept in the food web due to the polar conditions, the Arctic Ocean may also
represent an enormous carbon sink (Hirche and Mumm, 1992).
In the Fram Strait, the region between Svalbard to the east and Greenland to the west, the East Greenland
Current is the main outflow of polar water and ice from the Arctic Basin (Maykut, 1985) (Aagaard and
Coachman, 1968). The polar front (0° C isotherm and 34.5 isohaline at 50 m depth) extends approximately
along the continental shelf of Greenland, separating the polar surface water from the Arctic (Intermediate)
water and the marginal ice zone to the east (e.g. Aagaard and Coachman, 1968; Paquette et al., 1985). The
ice cover is densest in polar water, its extent to the east depends on the wind conditions (compare also Angelen
et al., 2011; Wadhams, 1981).
The seasonal latitudinal progression of increasing and diminishing light levels, respectively, is the determining
factor for the timing of the phytoplankton-related pelagic production. Therefore, the springbloom and ice break
up progress from south to north in spring, reaching the Arctic area by about June/July. Because the currents
in Fram Strait move in opposite direction, the polar East Greenland Current to the south, and the Atlantic West
Spitsbergen Current to the north, there is a delay of about a month between biological spring and summer
between the polar and the Atlantic side (Hirche et al., 1991). Therefore sea ice and the effect of melting ice
are important determinants of the ecosystem processes all along the East Greenland polar front from the
Greenland Sea through Fram Strait to the Arctic Basin (Legendre et al., 1992; Wassmann, 2011).
Ice situation
The Arctic Ocean develops towards a one-year instead of a multi-year sea-ice system with consequences for
the entire ecosystem, including ecosystem shifts, biodiversity loss, for water mass modifications and for its role
in the global overturning circulation. At its maximum, sea-ice covers 4.47 million km² in the Arctic Basin (Gill et
al., 2011): According to data from ice satellite observations in 1973-76 (NASA, 1987, in (Gill et al., 2011)),
permanent ice occupied 70-80% of the Arctic Basin area, and the interannual variability of this area did not
exceed 2%. Seasonal ice occupied 6-17% (before the melting period of the mid-1970s). Only in the first decade
of the 21st century, the permanent-ice area decreased to 6% in February 2008, concurrent with a rapid
increase in seasonal- ice. Whereas multiyear ice used to cover 50-60% of the Arctic, it covered less than 30%
in 2008, after a minimum of 10% in 2007. The average age of the remaining multiyear ice is also decreasing
from over 20 % being at least six years in the mid- to late 1980s, to just 6% of ice six years old or older in 2008.
c.f. Figure 2: Modelled ice age distribution in 1985-2000 (left) compared to February 2008 (right) (CAFF,
2010).
This trend is likely to amplify in the coming years, as the net ocean-atmosphere heat output due to the current
anomalously low sea ice coverage has approximately trippled compared to previous years, suggesting that
the present sea ice losses have already initiated a positive feedback loop with increasing surface air
temperatures in the Arctic (Kurtz et al., 2011).
About 10% of the sea ice in the Arctic basin is exported each year through Fram Strait into the Greenland Sea
(Maykut, 1985) which is therefore major sink for Arctic sea ice (Kwok, 2009). From 2001 to 2005, the summer
ice cover was so low on the East Greenland shelf, that it was more of a marginal ice zone (Smith Jr and Barber,
2007), however the subsequent record lows in overall Arctic ice cover brought about an increase in ice cover
off Greenland, which minimised the extent of the North East Water Polynia on the East Greenland shelf20, a
previously seasonally ice-free stretch of water (Wadhams, 1981).
Ice related biota
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http://www.issibern.ch/teams/Polynya/
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Allover the Arctic, an inventory of ice-associated biota presently counts over 1000 protists, and more than 50
metazoan species (Bluhm et al., 2011). The regionally very variable ice fauna (depends i.e. on ice age,
thickness, origin) consists of sympagic biota living within the caverns and brine channels of the ice, and
associated pelagic fauna. The most abundant and diverse sympagic groups of the ice mesofauna in the Arctic
seas are amphipods and copepods. Polar cod (Boreogadus saida) and partly Arctic cod (Arctogadus glacialis)
are dependent on the sympagic macro- and mesofauna for food, themselves being important food sources for
Arctic seals (such as ringed seal Phoca hispida) and birds, for example black guillemots Cephus grylle
(Bradstreet and Cross, 1982; Gradinger and Bluhm, 2004 and literature reviewed; Horner et al., 1992; Süfke
et al., 1998).
The higher the light level in the ice, the higher is the biomass of benthic algae as well as meiofauna and
microorganisms within the ice (Gradinger et al., 1991). Decreasing snow cover induces a feedback loop with
enhanced algal biomass increasing the heat absorption of the ice which leads to changes in the ice structure,
and ultimately the release of algae from the bottom layer (Apollonio, 1961 in Gradinger et al., 1991). Because
of the distance to land and shelves, and the thickness and internal structure of the multiyear pack ice over
deeper water, this type of ice has a fauna of its own (Carey, 1985; Gradinger et al., 1991). Arctic multiyear ice
floes can have very high algal biomasses in the brine channels and in the bottom centimeters which serves as
food for a variety of proto- and metazoans, usually smaller than 1 mm, over deep water (Gradinger et al.,
1999). In the central Arctic, ice algal productivity can contribute up to 50 % of the total primary productivity,
with lower contributions in the sea ice covered margins (Bluhm et al., 2011).
In the boundary layer between ice floes and the water column, another specific community exists which forms
the link between the ice based primary production and the pelagic fauna (Gradinger, 1995): large visible bands
of diatoms hang down from the ice, exploited by amphipods such as Gammarus wilkitzki, and occacionally by
water column copepods such as Calanus glacialis, which are important prey of for example polar cod
Boreogadus saida. The caverns, wedges and irregularities of the ice provide important shelter from predators
for larger ice associated species and provide an essential habitat for these species (Gradinger and Bluhm,
2004).
During melt, the entire sympagic ice biota are released into the water column where they may initiate the spring
algal plankton bloom (Smith and Sakshaug, 1990) or they may sink to the sea floor and serve as an episodic
and first food pulse for benthic organisms before pelagic production begins (Arndt and Pavlova, 2005). In
particular the shallow shelves and the shelf slope benthos has been shown to profit of this biomass input,
reflected in very rich benthic communities (Klitgaard and Tendal, 2004; Piepenburg, 2005).
The role of the polar front and marginal ice zone for the production system
Primary production in the Arctic Ocean is primarily determined by light availability, which is a function of ice
thickness, ice cover, snow cover, light attenuation), the abundance of both ice algae and phytoplankton,
nutrient availability and surface water stratification. Generally, the spring bloom occurs later further north and
in regions with a thick ice and snow cover. The current production period in the Arctic Ocean may extend to
120 days per year, with a total annual primary production in the central Arctic Ocean of probably up to 10 g C
m-2 (Wheeler et al., 1996).
Ice algae start primary production already at relatively low light levels when melting reduces the thickness of
the ice and snow cover. Only after the ice breaks up, when melting releases the ice biota into the water column
and meltwater leads to surface stratification, a major phytoplankton bloom of a few weeks develops, fuelling
the higher trophic foodweb of the Arctic (Gradinger et al., 1999, and literature quoted).
The marginal ice zones, i.e. where the ice gets broken up in warmer Atlantic or Arctic water, therefore play an
important role in the overall production patterns of the Arctic Ocean. Due to the strong water column
stratification and increased light levels involved with the melting of the ice, the location and recession of the
ice edge in spring and summer determines the timing and magnitude of the spring phytoplankton bloom, which
is generally earlier than in the open water (Gradinger and Baumann, 1991; Smith Jr et al., 1987). Wind- or
eddy-induced upwelling in the marginal ice zone, as well as biological regeneration processes replenish the
surface nutrient pool and therefore prolong the algal growth period (Gradinger and Baumann, 1991; Smith,
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1987). The hydrographic variability explains the patchy patterns of primary and secondary production
observed, as well as consequently the patchy occurrence of predators.
The polar front separates to some degree the pelagic faunas of the polar and Arctic waters in the Greenland
Sea and Fram Strait, each characterised by a few dominant copepod species with different life history
strategies (Hirche et al., 1991; see also review in Melle et al., 2005): In polar waters, Calanus glacialis uses
under ice plankton production and lipid reserves for initiating its spring reproduction phase, however depending
on the phytoplankton bloom for raising its offspring (e.g. Leu et al., 2011). Somewhat later, on the warm side
of the polar front in Arctic water, the Atlantic species Calanus finmarchicus uses the ice edge-related
phytoplankton bloom for secondary production. Calanus hyperboreus, the third and largest of the charismatic
copepod species has its core area of distribution in the Arctic waters of the Greenland Sea (Hirche, 1997;
Hirche et al., 2006).
Zooplankton of the Arctic Basin
Overall zooplankton biomass decreases towards the central Arctic basin, reaching a minimum in the most
northerly waters, i.e. the region with permanent ice cover (Mumm et al., 1998). However, investigations in
recent years demonstrated increased biomasses compared to studies several decades earlier - possibly a
consequence of the decrease in ice thickness and cover which only enabled the investigations to take place
from ship board.
There is a south-north decrease in zooplankton biomass, with a sharp decline north of 83°N (Hirche and
Mumm, 1992), coinciding with differences in the species composition of the biomass-forming zooplankton
species. Whereas the southern Nansen basin plankton is dominated by the Atlantic species Calanus
finmarchicus, entering the Arctic Basin with the West Spitsbergen Current, the northernmost branch of the
North Atlantic current, the Arctic and polar species Calanus hyperboreus and C. glacialis dominate the
biomass in the high-Arctic Amundsen and Makarov Basins (Auel and Hagen, 2002; Mumm et al., 1998). The
zooplankton species communities generally can be differentiated according to their occurrence in Polar
Surface Water (0-50 m, temperature below –1.7°C, salinity less than 33.0), Atlantic Layer (200–900 m;
temperature 0.5–1.5°C); salinity 34.5–34.8) and Arctic Deep Water (deeper than 1000 m, temperature -0,5-1° C, salinity > 34.9) (Auel and Hagen, 2002; Grainger, 1989; Kosobokova, 1982). The polar surface
community in the upper 50 m of the water column consists of original polar species as well as species
emerging from deeper Atlantic waters, alltogether leading to a high abundance and biomass peak in summer.
Diversity and biomass are minimal in the impoverished Arctic basin deepwater community (Kosobokova 1982).
Apart from a limited exchange with the Atlantic Ocean via the Fram Strait, the central Arctic deep-sea basins
are isolated from the rest of the world ocean deepsea fauna. Therefore, the bathypelagic fauna consists of a
few endemic Arctic species and some species of Atlantic origin. Due to the separation of the Eurasian and
Canadian Basins by the Lomonosov Ridge, significant differences in hydrographic parameters (Anderson et
al. 1994) and in the zooplankton composition occur between both basins (Auel and Hagen, 2002).
Fish
Polar cod, Boreogadus saida, is a keystone species in the ice-related foodwebs of the Arctic. Due to schooling
behavior and high energy content polar cod efficiently transfer the energy from lower to higher trophic levels,
such as seabirds, seals and some whales (Crawford and Jorgenson, 1993).
Seabirds
Ice cover is a physical feature of major importance to marine birds in high latitude oceans, providing access to
resources, refuge from aquatic predators (Hunt, 1990). As seabirds are dependant on leads between ice floes
or otherwise open water to access food, they search for the most productive waters in polynias (places within
the ice which are permanently ice free) and marginal ice zones (Hunt, 1990). Here they forage both on the
pelagic and sympagic ice-related fauna, especially the early stages of polar cod and the copepods Calanus
hyperboreus and C. glacialis. Likely, they benefit of the structural complexity and good visibility of their prey
near the ice (Hunt, 1990).
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In the Greenland Sea and Fram Strait, major breeding colonies exist on Svalbard, Greenland and on Jan
Mayen, all of these within reach of the seasonally moving marginal ice zone or a polynia (North East Water
Polynia on the East Greenland shelf). Breeding seabirds like Little auks (Alle alle), from colonies in the
northern Svalbard archipelago feed their offspring with prey caught in the vicinity of the nests, however
intermittently travel at least 100 km to the marginal ice zone at 80° N to replenish their body reserves (Jakubas
et al., Online 03 June 2011). Therefore, the distance of the marginal ice zone to the colony site is a critical
factor determining the breeding success (e.g. Joiris and Falck, 2011). Opportunistically, the birds also use
other zooplankton aggregations such as a in a cold core eddy in the Greenland Sea, closer to the nesting site
(Joiris and Falck, 2011).
A synopsis of seabird data for the period 1974–1993 (Joiris, 2000) showed that the little auk is one of the most
abundant species, together with the fulmar Fulmarus glacialis, kittiwake Rissa tridactyla and Brünnich’s
guillemot Uria lomvia in the European Arctic seas (mainly the Norwegian and Greenland Seas). In the
Greenland Sea and the Fram Strait, little auks represented the main species in polar waters, at the ice edge
and in closed pack ice, reaching more than 50% of all bird species (Joiris and Falck, 2011). In spring and
autumn, millions of seabirds pass through the area when migrating between their breeding sites on Svalbard
or the Russian Arctic and their wintering areas in Canada (Gill et al., 2011).
There are several seabird species in the European Arctic which are only met in ice-covered areas, for example
the Ivory gull Pagophila eburnea and the Thick-billed guillemot Uria lomvia (see e.g. CAFF, 2010): Both
species spend the entire year in the Arctic, and breed in close vicinity to sea ice although Thick-billed guillemots
were observed to fly up to 100 km from their colonies over open water to forage at the ice edge (Bradstreet
1979). The relatively rare Ivory gulls are closely associated with pack-ice, favouring areas with 70 – 90% ice
cover near the ice edge, where they feed on small fish, including juvenile Arctic cod, squid, invertebrates,
macro-zooplankton, carrion, offal and animal faeces (e.g. OSPAR Commission, 2009b). Ivory gulls have a low
reproductive rate and breeding only takes place if there is sufficient food, which makes the population highly
vulnerable to the effects of climate warming (e.g. OSPAR Commission, 2009b). Thick-billed guillemots are
relatively long lived and slow to reproduce and has a low resistance to threats including oil pollution, by-catch
in and competition with commercial fisheries operations, population declines due to hunting – particularly in
Greenland (OSPAR Commission, 2009c).
Ivory gull and Thick-billed guillemots are both listed by OSPAR as being under threat and/or decline, (OSPAR
Commission, 2008) and in 2011 recommendations for conservation action were agreed (OSPAR Commission,
2011) which will be implemented in conjunction with the circumpolar conservation actions of CAFF (CAFF,
1996; Gilchrist et al., 2008).
Marine mammals
Several marine mammal species permanently associate with sea ice in the European Arctic. These include
polar bear, walrus, and several seal species: bearded, Erignathus barbatus; ringed, Pusa hispida; hooded,
Cystophora cristata; and harp seal Pagophilus groenlandicus. Three whale species also occupy Arctic waters
year- round – narwhal, Monodon monoceros; beluga whale, Delphinapterus leucas; and bowhead whale,
Balaena mysticetus.
Polar bears Ursus maritimus are highly specialized for and dependent on the sea ice habitat and are therefore
particularly vulnerable to changes in sea ice extent, duration and thickness. They have a circumpolar
distribution limited by the southern extent of sea ice. Three subpopulations of polar bears occur in the European
high Arctic: the East Greenland, Barents Sea and Arctic Basin sub-populations, all with an unknown population
status (CAFF, 2010). Following the young-of-the-year ringed seal distribution, polar bears are most common
close to land and over the shelves, however some also occur in the permanent multi-year pack ice of the
central Arctic basin (Durner et al., 2009). Due to low reproductive rates and long lifetime, it is expected that
the polar bears will not be able to adapt to the current fast warming of the Arctic and become extirpated from
most of their range within the next 100 years (Schliebe et al., 2008).
Walrusses, Odobenus rosmarus, inhabit the Arctic ice year-round. They are conservative benthic feeders,
diving to 80-100 m depth for scaping off the rich mollusc fauna of the continental shelves, and need ice floes
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as resting and nursing platform close to their foraging grounds. Walrusses have been subject to severe hunting
pressure from the end of the 18th century to the mid 20th century, and are still hunted today in Greenland
(NAMMCO). By 1934, the estimated 70000-80000 individuals of the Atlantic population were reduced to 12001300, with none left on Svalbard (Weslawski et al., 2000). Todays relatively small sub-populations on the East
Greenland and Svalbard-Franz Josef Land coasts have recently shown a slightly increasing trend, in the latter
case reflecting the full protection of the species since the 1950´s (CAFF, 2010; NAMMCO). Apart from their
sensitivity to direct human disturbance and pollution, it is expected that walrusses will suffer from the changing
ice conditions (location, thickness for being used as haul-out site) as well as changes in ice-related productivity.
The Atlantic subspecies of the bearded seal, Erignathus barbatus occurs south of 85° N from the central
Canadian Arctic east to the central Eurasian Arctic, but no population estimates exist (Kovacs, 2008b).
Because of their primarily benthic feeding habits they live in ice covered waters overlying the continental shelf.
They are typically found in regions of broken free-floating pack ice; in these areas bearded seals prefer to use
small and medium sized floes, where they haul out no more than a body length from water and they use leads
within shore-fast ice only if suitable pack ice is not available (Kovacs, 2008b, and literature quoted).
The Arctic ringed seal Pusa (Phoca) hispida hispida has a very large population size and broad distribution,
however, there are concerns that future changes of Arctic sea ice will have a negative impact on the
population, some of which have already been documented in some parts of the subspecies range (Kovacs et
al., 2008). As the other seals, the ringed seal uses sea ice exclusively as their breeding, moulting and resting
(haulout) habitat, and feed on small schooling fish and invertebrates. In a co-evolution with one of their main
predators, the polar bear, they developed the ability to create and maintain breathing holes in relatively thick
ice, which makes them well adapted to living in fully ice covered waters allover the year.
The West Ice (or Is Odden) to the west of Jan Mayen, at approx. 72-73° N, in early spring a stretch of more of
less fast drift ice, is of crucial importance as a whelping and moulting area for harp seals and hooded seals
(summarised e.g. by ICES, 2008). Discovered in the early 18th century, up to 350000 seals (1920s) were killed
per year, decimating the populations from an estimated one million individuals in the 1950s (Ronald et al.,
1982) to today´s 70000 and 243000 of hooded and harp seals, respectively (Kovacs, 2008a, c).
Hooded seal, Cystophora cristata, is a pack ice species, which is dependent on ice as a substrate for pupping,
moulting, and resting and as such is vulnerable to reduction in extent or timing of pack ice formation and
retreat, as well as ice edge related changes in productivity (Kovacs, 2008a, and literature quoted). Hooded
Seals feed on a wide variety of fish and invertebrates, including species that occur throughout the water
column. After breeding an moulting on the West Ice they follow the retreating pack ice to the north, but also
spend significant periods of time pelagically, without hauling out (Folkow and Blix 1999) in (Kovacs, 2008a).
The northeast Atlantic breeding stock has declined by 85-90 % over the last 40-60 years. The cause of the
decline is unknown, but very recent data suggests that it is on-going (30% within 8 years), despite the protective
measures that have been taken in the last few years. The species is therefore considered to be vulnerable
(Kovacs, 2008a).
Harp seals Pagophilus (Phoca) groenlandicus are the most numerous seal species in the Arctic seas. Their
reproduction takes place in huge colonies, for example on the pack ice of the ‘‘West Ice’’ north of Jan Mayen,
and after the breeding season they follow the retreating pack ice edge northwards up to 85° N, feeding mainly
on polar cod under the ice (Kovacs, 2008c) .
Narwhals Monodon monoceros primarily inhabit the ice-covered waters of the European Arctic, including the
ice sheet off East Greenland (Jefferson et al., 2008b). For two months in summer, they visit the shallow fjords
of East Greenland, spending all the rest of the year offshore, in deep ice-covered waters along the continental
slope in the Greenland Sea and Arctic Basin (Heide-Jørgensen and Dietz, 1995). Narwhals are deep diving
benthic feeders and forage on fish, squid, and shrimp, especially Arctic fish species, such as Greenland halibut,
Arctic cod, and polar cod at up to 1500 m depth and mostly in winter. A recent assessment of the sensitivity of
all Arctic marine mammals to climate change ranked the narwhal as one of the three most sensitive species,
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primarily due to its narrow geographic distribution, specialized feeding and habitat choice, and high site fidelity
(Laidre et al. 2008 in (Jefferson et al., 2008b)).
Bowhead whales Balaena mysticetus are found only in Arctic and subarctic regions and a Svalbard-Barents
population occurs from the coast of Greenland across the Greenland Sea to the Russian Arctic. They spend
all of their lives in and near openings in the pack ice feeding on small to medium-sized zooplankton. They
migrate to the high Arctic in summer, and retreat southward in winter with the advancing ice edge (Moore and
Reeves 1993 in (Reilly et al., 2008)). Whaling has decimated the original bowhead whale populations to be
rare nowadays, listed by OSPAR as being under threat and/or decline (OSPAR Commission, 2008). The
species is considered to be very sensitive to changes in the ice-related ecosystem as well as sound
disturbance, possible consequences of a progressive reduction of ice cover (OSPAR Commission, 2009a).
Belugas Delphinapterus leucas prefer coastal and continental shelf waters with a broken-up ice cover. They
have never been surveyed around Svalbard. Pods numbering into the thousands are sighted irregularly around
the archipelago, and pods ranging from a few to a few hundred individuals are seen regularly (Gjertz and Wiig
1994; Kovacs and Lydersen 2006 in (Jefferson et al., 2008a)).
Little is known about the populations of the larger fauna in the Central Arctic Basin over the deepsea basins
and ridges. But it is not likely that it is currently an area of great abundance - too far from the coastal nesting
sites of marine birds, and over too deep water to allow feeding on benthos, as most of the larger mammals
would need, and currently of too low plankton production to feed the large whales. All of these groups have
their distribution center along the continental shelves presently - however, following the receeding ice edge
out to the central Arctic basin may be one of the options for the future.
Feature condition, and future outlook
This high Arctic region is particularly vulnerable to the the loss of ice cover and other effects of the anticipated
global warming, including elevated UV radiation levels (Agustí, 2008). (Wassmann et al., 2010) summarise
what changes may be expected within the subarctic/Arctic region:
•
northward displacement (range shifts) of subarctic and temperate species, and cross-Arctic transport
of organisms;
•
increased abundance and reproductive output of subarctic species, decline and reduced reproductive
success of some Arctic species associated with the ice and species now preyed upon by predators
whose preferred prey have declined;
•
increased growth of some subarctic species and primary producers, and reduced growth and condition
of animals that are bound to, associated with, or born on the ice;
•
anomalous behaviour of ice-bound, ice-associated, or ice-born animals with earlier spring events and
delayed fall events;
•
changes in community structure due to range shifts of predators resulting in changes in the predator–
prey linkages in the trophic network.
(Wassmann, 2008) expects radical changes in the productivity, functional relationships and biodiversity of the
Arctic Ocean. He suggests that a warmer climate with less ice cover will result in greater primary production,
a reduction of the stratified water masses to the south, changes in the relationship between biological
processes in the water column and the sediments, a reduction in niches for higher trophic levels and a
displacement of Arctic by boreal species. On the shelves, increased sediment discharges are expected to
lower the primary production due to higher turbidity, and enhance the organic input to the deep ocean. A more
extensive review of expected or suspected consequences of climate change for the marine system of the Arctic
is given in (Loeng et al., 2005).
Figure 3, extracted from (Gill et al., 2011), presents the conceptual ideas about possible Arctic ecosystem
changes mediated by human impact:
ICES Advice 2013, Book 1
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The normal situation shown in the upper left panel consists of ice-dependent species and species that tolerate
a broader range of temperatures and are found in waters with little or no sea ice. Primary production occurs in
phytoplankton (small dots in the figure) in ice-free waters and in ice-attached algae and phytoplankton in icecovered waters. Phytoplankton (small t-shaped symbols in the figure) and ice algae are the main food sources
for zooplankton and benthic animals. The fish community consists of both pelagic and demersal species.
Several mammals are ice-associated, including polar bears and several species of seals. A number of sea bird
species are also primarily associated with ice-covered waters.
At moderate temperature increases (upper right) populations of ice-dependent species are expected to decline
as sea ice declines, and sub-Arctic species are expected to move northwards. Arctic benthic species are
expected to decline, especially if their distributions are pushed close to or beyond the continental slope.
The expected effects from fisheries relate to the continental shelves. Two major effects are reductions in
populations of benthic organisms due to disturbance from bottom trawling and removal of large individuals in
targeted fish stocks. In addition, the size of targeted stocks, both demersal and pelagic, may be reduced.
In addition, the effects of ocean acidification are considered (lower right). Ocean acidification will result in
depletion of carbonate phases such as aragonite and calcite. This will alter the structure and function of
calcareous organisms, particularly at lower trophic levels. Changes in pH can also alter metabolic processes
in a range of organisms. It is not known how these changes will propagate to higher trophic levels, but the
effects could be substantial.
c.f. Figure 3: Conceptual models showing potential impacts on Arctic marine ecosystems under different
scenarios (Gill et al., 2011).
(Gill et al., 2011) conclude that the central part of the Arctic Basin is not a region for fisheries or oil and gas
exploration. However, this region has played and will continue to play a very important role in the redistribution
of pollutants, due to ice drift and/or currents between coastal and shelf areas and the Arctic Basin peripheries,
far from sources of pollution.
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Assessment against CBD EBSA Criteria
Table 1. relation of each of the CBD criteria to the proposed area relating to the best available science. Note
that a candidate EBSA may qualify on the basis of one or more of the criteria, the boundaries of the EBSA
need not be defined with exact precision.
CBD EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Know
Uniqueness or The area contains either (i) unique (“the only one
rarity
of its kind”), rare (occurs only in few locations) or
endemic species, populations or communities,
and/or (ii) unique, rare or distinct, habitats or
ecosystems; and/or (iii) unique or unusual
geomorphological or oceanographic features
Low
Some
High
x
Explanation for ranking
Arctic sea ice, in particular the multiyear ice of the Central Arctic is globally unique and hosts endemic
species such as the Gammarid amphipod Gammarus wilkitzki and sea ice meiofauna which will disappear
with the melting of the ice. Polar bears, walrusses, bowhead whales, narwhales, belugas, several seal
species and many bird species are endemic to the high Arctic ice.
While sea ice species such as G. wilkitzki are not endemic to the proposed EBSA they are endemic to the
Arctic and unique within the OSPAR area
Special
Areas that are required for a population to
importance for survive and thrive
life-history
stages of
species
x
Explanation for ranking
Sea ice is essential for its sympagic fauna, and to some extent also for the pelagic associated fauna which
also depends on the right timing of biomass production (match/mismatch with bloom periods). The marginal
ice zone and other openings in the ice are essential feeding grounds for a large number of ice-associated
species which exploit the seasonallly high production there.
At present the area covered by the proposed EBSA is ice-covered throughout the summer but although
there is no marginal ice zone there will be an ice zone community present, thus the sea ice is essential to
maintain the sympagic biological community and associated ecosystem functions.
ICES Advice 2013, Book 1
261
Importance for
threatened,
endangered or
declining
species and/or
habitats
Area containing habitat for the survival and
recovery of endangered, threatened, declining
species or area with significant assemblages of
such species
x
Explanation for ranking
The high arctic ice hosts endemic species such as the Gammarid amphipod Gammarus wilkitzki and sea ice
meiofauna which will disappear with the melting of the ice. Many of the obligatory ice-related species are
listed as vulnerable by IUCN, and/or listed as under threat and/or decline by OSPAR, examples include the
Ivory gull, thick-billed guillemot, bowhead whale, hooded seal and polar bear. With the overall trend of
retreating sea ice extent, the proposed EBSA may become increasingly important for all ice-dependent
species in the future.
Vulnerability,
fragility,
sensitivity, or
slow recovery
Areas that contain a relatively high proportion of
sensitive habitats, biotopes or species that are
functionally fragile (highly susceptible to
degradation or depletion by human activity or by
natural events) or with slow recovery
x
Explanation for ranking
The ice-related foodweb and ecosystem is highly sensitive to the ecological consequences of a warming
climate. Beyond this the Arctic is at the forefront of the impacts of ocean acidification (Wicks & Roberts
2012). The largest changes in ocean pH will occur in the Arctic Ocean, with complete undersaturation of the
Arctic Ocean water column predicted before the end of this century (Steinacher et al. 2009). Many of the
seabird and mammal populations are particularly sensitive to changes due to their already low population
numbers, and low fertility. If the retreat of the ice to the north will lead to increased shipping and oil and gas
exploitation in Arctic waters, the increased risk of spills would also pose a potential hazard for example for
guillemots, which are extremely susceptible to mortality from oil pollution (CAFF, 2010). In addition, some
species like Ivory gull are sensitive to an increased heavy metal load in their prey.
Biological
productivity
Area containing species, populations or
communities with comparatively higher natural
biological productivity
Explanation for ranking
This criterion was not evaluated in the OSPAR/NEAFC/CBD Workshop. ICES did not have enough
information to evaluate this criterion.
Biological
diversity
262
Area contains comparatively higher diversity of
ecosystems, habitats, communities, or species,
or has higher genetic diversity
ICES Advice 2013, Book 1
Explanation for ranking
This criterion was not evaluated in the OSPAR/NEAFC/CBD Workshop. ICES did not have enough
information to evaluate this criterion.
References
Aagaard, K., 1989. A synthesis of Arctic Ocean circulation. Rapport Proces et Verbeaux Réunion du Conseil
international pour l'Exploration de la Mer 188, 11-22.
Aagaard, K., Coachman, L.K., 1968. The East Greenland Current north of Denmark Strait: Part II. Arctic 21,
267-290.
Aagaard, K., Swift, J.H., Carmack, E.C., 1985. Thermohaline circulation in the Arctic mediterranean seas.
Journal of Geophysical Research 90, 4833-4846.
Agustí, S., 2008. Impacts of increasing ultraviolet radiation on the polar oceans. In: Impacts of global
warming on polar ecosystems. Duarte, C.M. (Ed.) Fundación BBVA pp. 25-46.
Anderson, L.G., Jones, E.P., Koltermann, K.P., Schlosser, P., Swift, J.H., Wallace, D.W.R., 1989. The first
oceanographic section across the Nansen Basin in the Arctic Ocean. Deep Sea Research 36, 475482.
Angelen, J.H.v., Broeke, M.R.v.d., Kwok, R., 2011. The Greenland Sea Jet: A mechanism for wind‐driven
sea ice export through Fram Strait. Geophysical Research Letters 38 (L12805).
Anisimov, O.A., Vaughan, D.G., Callaghan, T.V., Furgal, C., Marchant, H., Prowse, T.D., Vilhjálmsson, H.,
Walsh, J.E., 2007. Polar regions (Arctic and Antarctic). In: Climate Change 2007: Impacts, Adaptation
and Vulnerability. Contribution of Working Group II to the Fourth Assessment Report of the
Intergovernmental Panel on Climate Change. Parry, M.L., Canziani, O.F., Palutikof, J.P., Linden,
P.J.v.d., Hanson, C.E. (Eds.)Cambridge University Press, Cambridge pp. 653-685.
Arndt, C., E. , Pavlova, O., 2005. Origin and fate of ice fauna in the Fram Strait and Svalbard area. Marine
Ecology Progress Series 301, 55-66.
Auel, H., Hagen, W., 2002. Mesozooplankton community structure, abundance and biomass in the central
Arctic Ocean. Marine Biology 140, 1013-1021.
Bluhm, B.A., Gebruk, A.V., Gradinger, R., Hopcroft, R.R., Huettmann, F., Kosobokova, K.N., Sirenko, B.I.,
Weslawski, J.M., 2011. Arctic marine biodiversity: An update of species richness and examples of
biodiversity change. Oceanography 24 (3), 232-248.
Bradstreet, M.S.M., Cross, W.E., 1982. Trophic relationships at high Arctic ice edges. Arctic 35 (1), 1-12.
CAFF, 1996. International Murre conservation strategy and action plan. CAFF International Secretariat,
CAFF Circumpolar Seabird Working Group, Akureyri, Iceland, pp. 1-16.
CAFF, 2010. Arctic Biodiversity Trends 2010. Selected indicators of change. CAFF International Secretariat,
, Akureyri, Iceland.
Carey, A.G.I., 1985. Marine Ice Fauna. In: Arctic Sea Ice Biota. A., H.R. (Ed.)CRC Press, Boca Raton.
Florida pp. 17-190
Crawford, R.E., Jorgenson, J.K., 1993. Schooling behaviour of arctic cod, Boreogadus saida in relation to
drifting pack ice. Environmental Biology of Fishes 36 (4), 345-357.
Durner, G.M., Douglas, D.C., Nielson, R.M., Amstrup, S.C., McDonald, T.L., Stirling, I., Mauritzen, M., Born,
E.W., Wiig, Ø., Deweaver, E., Serreze, M.C., Belikov, S.E., Holland, M.M., Maslanik, J., Aars, J.,
Bailey, D.A., Derocher, A.E., 2009. Predicting 21st-century polar bear habitat distribution from global
climate models. Ecological Monographs 79 (1), 25-58.
ICES Advice 2013, Book 1
263
Edmonds, H.N., Michael, P.J., Baker, E.T., Connelly, D.P., Snow, J.E., Langmuir, C.H., Dick, H.J.B., Mühe,
R., German, C.R., Graham, D.W., 2003. Discovery of abundant hydrothermal venting on the ultraslowspreading Gakkel ridge in the Arctic Ocean. Nature 421, 252-256.
Gilchrist, G., Strøm, H., Gavrilo, M.V., Mosbech, A., 2008. International Ivory Gull conservation strategy and
action plan. CAFF International Secretariat, Circumpolar Seabird Group (CBird). CAFF Technical
Report No. 18.
Gill, M.J., Crane, K., Hindrum, R., Arneberg, P., Bysveen, I., Denisenko, N.V., Gofman, V., Grant-Friedman,
A., Gudmundsson, G., Hopcroft, R.R., Iken, K., Labansen, A., Liubina, O.S., Melnikov, I.A., Moore,
S.E., Reist, J.D., Sirenko, B.I., Stow, J., Ugarte, F., Vongraven, D., Watkins, J., 2011. Arctic Marine
Biodiversity Monitoring Plan (CBMP-MARINE PLAN), CAFF Monitoring Series Report No.3, April
2011. CAFF International Secretariat,, Akureyri, Iceland.
Gradinger, R., 1995. Climate change and biological oceanography of the Arctic Ocean. Phil. Trans. R. Soc.
A 352, 277-286.
Gradinger, R., Bluhm, B.A., 2004. In situ observations on the distribution and behavior of amphipods and
Arctic cod (Boreogadus saida) under the sea ice of the high Arctic Canadian Basin. Polar Biology 27,
595-603.
Gradinger, R., Friedrich, C., Spindler, M., 1999. Abundance, biomass and composition of the sea ice biota of
the Greenland Sea pack ice. Deep Sea Research 46, 1457-1472.
Gradinger, R., Spindler, M., Henschel, D., 1991. Development o Arctic sea-ice organisms under graded
snow cover. In: Proceedings of the Pro Mare Symposium on Polar Marine Ecology. Sakshaug, E., E.,
H.C.C., Øritsland, N.A. (Eds.), Polar Research 10 (1), Trondheim pp. 295-307.
Gradinger, R.R., Baumann, M.E.M., 1991. Distribution of phytoplankton communities in relation to the largescale hydrographical regime in the Fram Strait. Mar. Biol. 111, 311-321.
Grainger, E.H., 1989. Vertical distribution of zooplankton in the central Arctic Ocean. In: Proc 6th Conf
Comite´Arctique Int 1985. Rey, L., Alexander, V. (Eds.) Brill Leiden pp. 48–60.
Heide-Jørgensen, M.P., Dietz, R., 1995. Some characteristics of narwhal, Monodon monoceros, diving
behaviour in Baffin Bay. Canadian Journal of Zoology 73, 2106-2119.
Hirche, H.J., 1997. Life cycle of the copepod Calanus hyperboreus in the Greenland Sea. Marine Biology
128 (4), 607-618.
Hirche, H.J., Baumann, M.E.M., Kattner, G., Gradinger, R., 1991. Plankton distribution and the impact of
copepod grazing on primary production in Fram Strait, Greenland Sea. Journal of Marine Systems 2
(3-4), 477-494.
Hirche, H.J., Mumm, N., 1992. Distribution of dominant copepods in the Nansen Basin, Arctic Ocean, in
summer. Deep Sea Research Part A. Oceanographic Research Papers 39 (2, Part 1), S485-S505.
Hirche, H.J., Muyakshin, S., Klages, M., Auel, H., 2006. Aggregation of the Arctic copepod Calanus
hyperboreus over the ocean floor of the Greenland Sea. Deep Sea Research Part I: Oceanographic
Research Papers 53 (2), 310-320.
Horner, R., Ackley, S.F., Dieckmann, G.S., Gulliksen, B., Hoshiai, T., Legendre, L., Melnikov, I.A., Reeburgh,
W.S., Spindler, M., Sullivan, C.W., 1992. Ecology of sea ice biota. Habitat, terminology, and
methodology. Polar Biology 12 (3), 417-427.
Hunt, G.L.J., 1990. The pelagic distribution of marine birds in a heterogeneous environment. Polar Research
8, 43-54.
ICES, 2008. Report of the ICES Advisory Committee In: ICES Advice, Book 3, The Barents and the
Norwegian SEa.
Jakubas, D., Iliszko, L., Wojczulanis-Jakubas, K., Stempniewicz, L., Online 03 June 2011. Foraging by little
auks in the distant marginal sea ice zone during the chick-rearing period. Polar Biology, 1-9.
264
ICES Advice 2013, Book 1
Jefferson, T.A., Karczmarski, L., Laidre, K., O’Corry-Crowe, G., Reeves, R.R., Rojas-Bracho, L., Secchi,
E.R., Slooten, E., Smith, B.D., Wang, J.Y., Zhou, K., 2008a. Delphinapterus leucas In: IUCN 2011.
IUCN Red List of Threatened Species. Version 2011.1. www.iucnredlist.org Downloaded on 31
August 2011.
Jefferson, T.A., Karczmarski, L., Laidre, K., O’Corry-Crowe, G., Reeves, R.R., Rojas-Bracho, L., Secchi,
E.R., Slooten, E., Smith, B.D., Wang, J.Y., Zhou, K., 2008b. Monodon monoceros. In: IUCN 2011.
IUCN Red List of Threatened Species. Version 2011.1. . www.iucnredlist.org Downloaded on 31
August 2011.
Joiris, C., Falck, E., 2011. Summer at-sea distribution of little auks Alle alle and harp seals Pagophilus
(Phoca) groenlandica in the Fram Strait and the Greenland Sea: impact of small-scale hydrological
events. Polar Biology 34 (4), 541-548.
Joiris, C.R., 2000. Summer at-sea distribution of seabirds and marine mammals in polar ecosystems: a
comparison between the European Arctic seas and the Weddell Sea, Antarctica. Journal of Marine
Systems 27, 267-276.
Klitgaard, A.B., Tendal, O.S., 2004. Distribution and species composition of mass occurrences of large-sized
sponges in the northeast Atlantic. Progress in Oceanography 61, 57-98.
Kosobokova, K.N., 1982. Composition and distribution of the biomass of zooplankton in the central Arctic
Basin. Oceanology 22, 744-750.
Kovacs, K., 2008a. Cystophora cristata. IUCN 2011. IUCN Red List of Threatened Species. Version 2011.1.
www.iucnredlist.org Downloaded on 31 August 2011.
Kovacs, K., 2008b. Erignathus barbatus. IUCN 2011. IUCN Red List of Threatened Species. Version 2011.1.
www.iucnredlist.org Downloaded on 31 August 2011.
Kovacs, K., 2008c. Pagophilus groenlandicus. IUCN 2011. IUCN Red List of Threatened Species. Version
2011.1. www.iucnredlist.org Downloaded on 31 August 2011.
Kovacs, K., Lowry, L., Härkönen, T., 2008. Pusa hispida. In: IUCN 2011. IUCN Red List of Threatened
Species. Version 2011.1. . www.iucnredlist.org Downloaded on 31 August 2011.
Kwok, R., 2009. Outflow of Arctic Ocean sea ice into the Greenland and Barents seas: 1979-2007. Journal of
Climate 22, 2438-2456.
Legendre, L., Ackley, S.F., Dieckmann, G.S., Gulliksen, B., Horner, R., Hoshiai, T., Melnikov, I.A., Reeburgh,
W.S., Spindler, M., Sullivan, C.W., 1992. Ecology of sea ice biota. Polar Biology 12 (3), 429-444.
Leu, E., Søreide, J.E., Hessen, D.O., Falk-Petersen, S., Berge, J., 2011. Consequences of changing sea ice
cover for primary and secondary producers in the European Arctic shelf seas: timing, quantity, and
quality. Progress in Oceanography 90, 18-32.
Loeng, H., Brander, K., Carmack, E.C., Denisenko, S., Drinkwater, K., Hansen, B., Kovacs, K., Livingston,
P., McLaughlin, F., Sakshaug, E., 2005. Marine systems. In: Arctic Climate Impact Assessment,
ACIA. Symon, C., Arrisand, L., Heal, B. (Eds.),Cambridge University Press, Cambridge pp. 453-538.
Mauritzen, C., Hansen, E., Andersson, M., Berx, B., Beszczynska-Möller, A., Burud, I., Christensen, K.H.,
Debernard, J., de Steur, L., Dodd, P., Gerland, S., Godøy, Ø., Hansen, B., Hudson, S., Høydalsvik, F.,
Ingvaldsen, R., Isachsen, P.E., Kasajima, Y., Koszalka, I., Kovacs, K.M., Køltzow, M., LaCasce, J.,
Lee, C.M., Lavergne, T., Lydersen, C., Nicolaus, M., Nilsen, F., Nøst, O.A., Orvik, K.A., Reigstad, M.,
Schyberg, H., Seuthe, L., Skagseth, Ø., Skar∂hamar, J., Skogseth, R., Sperrevik, A., Svensen, C.,
Søiland, H., Teigen, S.H., Tverberg, V., Wexels Riser, C., 2011. Closing the loop - Approaches to
monitoring the state of the Arctic Mediterranean during the International Polar Year 2007-2008.
Progress in Oceanography 90 (1-4), 62-89.
Maykut, G.A., 1985. The ice environment. In: Sea-ice biota. Horner, R. (Ed.)CRC Press, Boca Raton pp. 2182.
ICES Advice 2013, Book 1
265
Melle, W., Ellertsen, B., Skjoldal, H.R., 2005. Zooplankton: The link to higher trophic levels. In: The Nordic
Seas: An integrated perspective oceanography, climatology, biogeochemistry, and modelling. .
Drange, H., Dokken, T., Furevik, T., Gerdes, R., Berger, W. (Eds.)Geophysical Monograph Series 158
pp. 137-202.
Mumm, N., Auel, H., Hanssen, H., Hagen, W., Richter, C., Hirche, H.J., 1998. Breaking the ice: large-scale
distribution of mesozooplankton after a decade of Arctic and transpolar cruises. Polar Biology 20 (3),
189-197.
NAMMCO, The Atlantic Walrus. North Atlantic Marine Mammal Commission. Status of Marine Mammals in
the North Atlantic, Tromsø, pp. 1-7.
OSPAR Commission, 2008. OSPAR List of Threatened and/or Declining Species andHabitats. Reference
number 2008-6. http://www.ospar.org/documents/dbase/decrecs/agreements/0806e_ospar%20list%20species%20and%20habitats.doc.
OSPAR Commission, 2009a. Background Document for Bowhead whale Balaena mysticetus. OSPAR
Commission, Biodiversity Series 494/2010, pp. 1-20.
OSPAR Commission, 2009b. Background Document for Ivory gull Pagophila eburnea. OSPAR Commission,
Biodiversity Series 410/2009, pp. 1-16.
OSPAR Commission, 2009c. Background Document for Thick-billed murre Uria lomvia. OSPAR
Commission, Biodiversity Series 416/2009, pp. 1-20.
OSPAR Commission, 2011. Meeting of the OSPAR Commission (OSPAR) London: 20-24 June 2011.
Summary Record OSPAR 11/20/1-E. OSPAR Commission, London.
Paquette, R., Bourke, R., Newton, J., Perdue, W., 1985. The East Greenland Polar Front in autumn. Journal
of Geophysical Research 90 (C3), 4866-4882.
Piepenburg, D., 2005. Recent research on Arctic benthos: common notions need to be revised. Polar
Biology 28 (10), 733-755.
Reilly, S.B., Bannister, J.L., Best, P.B., Brown, M., , Brownell Jr., R.L., Butterworth, D.S., Clapham, P.J.,
Cooke, J., Donovan, G.P., Urbán, J., Zerbini, A.N., 2008. Balaena mysticetus. In: IUCN 2011. IUCN
Red List of Threatened Species. Version 2011.1. . www.iucnredlist.org Downloaded on 31 August
2011.
Renaud, P.E., Caroll, M.L., Ambrose, W.G.J., 2008. Effects of global warming on Arctic seafloor communities
and its consequences for higher trophic levels. In: Impacts of global warming on polar ecosystems.
Duarte, C.M. (Ed.)Fundación BBVA pp. 141-177.
Rey, F., 2004. Phytoplankton: the grass of the sea. In: The Norwegian Sea Ecosystem. Skjoldal, H.R.
(Ed.)Tapir Academic Press, Trondheim, Norway pp. 97-136.
Ronald, K., Healey, P.J., Fisher, H.D., 1982. The harp seal, Pagophilus groenlandicus. In: Small cetaceans,
seals, sirenians and otters. FAO Fisheries Series No. 5, Vol. IV, Food and Agriculture Organisation of
the United Nations. Workding Party on Mammals.
Schliebe, S., Wiig, Ø., Derocher, A.E., Lunn, N., 2008. Ursus maritimus. In: IUCN 2011. IUCN Red List of
Threatened Species. Version 2011.1. www.iucnredlist.org Downloaded on 31 August 2011.
Smith Jr, W.O., Barber, D., 2007. Polynyas and climate change: a view to the future. In: Polynays, windows
to the world. Halpern, D. (Ed.), Elsevier Oceanography Serie 74, Elsevier, Amsterdam pp. 411-420.
Smith Jr, W.O., Baumann, M.E.M., Wilson, D.L., Aletsee, L., 1987. Phytoplankton biomass and productivity
in the Marginal Ice Zone of the Fram Strait during summer 1984. Journal of Geophysical Research 92
(C7), 6777-6786.
Smith, W.O.J., 1987. Phytoplankton dynamics in the marginal ice zones. Oceanography and Marine Biology
Annual Review 25, 11-38.
266
ICES Advice 2013, Book 1
Smith, W.O.J., Sakshaug, E., 1990. Polar phytoplankton. In: Polar oceanography. Part B. Chemistry, biology
and geology. Smith Jr, W.O. (Ed.) Academic Press, San Diego pp. 477-525.
Steinacher, M., Joos, F., Frölicher, T., Plattner, G. & Doney, S.c. 2009. Imminent ocean acidification in the
Arctic projected with the NcAR global coupled carbon cycle-climate model. Biogeosciences 6, 515–
533.
Süfke, L., Piepenburg, D., Dorrien, C.C.v., 1998. Body size, sex ratio and diet composition of Arctogadus
glacialis (Peters, 1874) (Pisces: Gadidae) in the Northeast Water Polynya (Greenland). Polar Biology
20, 357-363.
Wadhams, P., 1981. The ice cover in the Greenland and Norwegian Seas. Rev. Geophys. Space Physics
19, 345-393.
Wassmann, P., 2008. Impacts of global warming on Arctic pelagic ecosystems and processes. In: Impacts
of global warming on polar ecosystems. Duarte, C.M. (Ed.)Fundación BBVA pp. 113-148.
Wassmann, P., 2011. Arctic marine ecosystems in an era of rapid climate change. Progress in
Oceanography 90, 1-17.
Wassmann, P., Duarte, C.M., Agustí, S., Seijr, M., 2010. Footprints of climate change in the Arctic Marine
Ecosystem. Biological Global Change.
Weslawski, J.M., Hacquebord, L., Stempniewicz, L., Malinga, M., 2000. Greenland whales and walruses in
the Svalbard food web before and after exploitation. Oceanologia 42 (1), 37-56.
Wheeler, P.A., Gosselin, M., Sherr, E., Thibault, D., Kirchman, D.L., Benner, R., Whitledge, T.E., 1996.
Active cycling of organic carbon in the central Arctic Ocean. Nature 380, 697-699.
Wicks, L., Roberts, J.M. (2012) Benthic invertebrates in a high CO2 world. Oceanography & Marine Biology:
An Annual Review 50: 127 -188
Maps and Figures
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Figure 1: Location of the Ecologically or biologically significant areas (EBSA) proposed by WWF in
September 2011. The position of the Arctic and polar fronts was redrawn after (Rey, 2004, Fig. 5.7).
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Figure 2: Modelled ice age distribution in 1985-2000 (left) compared to February 2008 (right) (CAFF, 2010).
Figure 3: Conceptual models showing potential impacts on Arctic marine ecosystems under different
scenarios (Gill et al., 2011).
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1.5.6.6
Special request, Advice June 2013
ECOREGION
SUBJECT
General advice
OSPAR/NEAFC special request on existing and potential new management
measures for ecologically and biologically significant areas (EBSAs)
Advice summary
ICES provides a summary of management measures already implemented within ecologically and biologically significant
areas (EBSAs). ICES notes that there are numerous measures already in place by both NEAFC and by OSPAR (as requests
to Contracting Parties) and by other competent management authorities, and that both generic and targeted management
measures may offer protection to the features that would qualify as meeting EBSA criteria. The performance of these
measures has not been evaluated and it was not possible to assess whether these measures are sufficient to protect all of
the features that would qualify under EBSA criteria from all potential threats, or whether further measures are required.
ICES notes that some specific areas may need further protective measures.
Request
c) For the use of OSPAR and NEAFC Contracting Parties, as appropriate, provide a separate document with additional
relevant information and up-to-date accounts of the relevant management measures already implemented within the
individual EBSAs.
d) In a separate document, describe potential new management measures within individual EBSAs if appropriate.
ICES advice
ICES summarized the existing management measures or recommendations of bodies with regulatory or coordinating
authority for the major sectoral activities in the OSPAR and NEAFC areas, and, where they exist, those of the authorities
for conservation and protection of special components of biodiversity. Some of the measures apply directly, while others
require implementing legislation by national authorities (or in some cases by the EU). The power to require vessels to
operate in specified ways lies with the Flag State of each vessel.
ICES does not have information on the performance of many of the existing measures, and consequently has not been
able to evaluate whether these management measures would be sufficient to protect all of the features that would qualify
under EBSA criteria from all potential threats. Nonetheless a range of generic and spatially targeted protective
management measures already exist within the EBSA areas. There are, however, some exceptions that may need improved
protective measures:
•
•
•
Josephine Seamount
The Hatton–Rockall basin
The existing fishing areas that lie north of the Azores on the Mid-Atlantic Ridge. One of these is a potential
threat to hydrothermal vents in the area.
ICES advises that a systematic review of the performance of the existing measures and how they interact to reduce threats
to EBSAs is needed before any new management measures could be sensibly considered through a gap analysis. ICES
makes the following general suggestions that are likely to improve the protection of EBSAs in the Northeast Atlantic:
•
•
•
•
Protective measures for vulnerable marine ecosystems (VMEs) should be made permanent. In many cases these
measures are only temporary. This is not appropriate for the long-lived, sessile organisms within VMEs.
Accessibility of existing ecological and fisheries data should be improved through a concerted effort between
relevant authorities.
Coordination of competent authorities should be improved in the selection and adoption of measures in order to
help ensure efficient implementation.
Observer coverage of fishing vessels operating within EBSAs should be increased.
Management measures
North-East Atlantic Fisheries Commission (NEAFC)
Table 1.5.6.6.1 summarizes NEAFC regulations for fishing activities within nine of the ten proposed EBSAs. The Arctic
ice habitat lies outside the regulatory area of NEAFC. The ten proposed EBSA areas are shown in Figure 1.5.6.6.1,
together with existing bottom fisheries closures enforced by NEAFC and high seas MPAs established by OSPAR. Since
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ICES Advice 2013, Book 1
2005, NEAFC has closed 14 areas to bottom fishing to protect VMEs. In addition (for fisheries management rather than
VME protection), NEAFC has closed an area for haddock on Rockall Bank since 2001 and enforced a seasonal closed
area on the Reykjanes Ridge to protect a blue ling spawning ground. In total the area closed to protect VMEs is in excess
of 600 000 square kilometres and covers all areas where the presence of VMEs have been validated up to the end of 2012.
ICES has recently provided further advice on the boundaries of some of these VMEs (ICES, 2013a).
NEAFC has different bottom-fishing regulations for existing fisheries areas and new fishing areas. Five of the proposed
EBSAs are covered by the ‘New Fishing Area’ regulations only. Exploratory fishing in new areas is only authorized under
strict conditions that include full observer coverage. There have been no applications for exploratory fishing since the
regulations were adopted. Several points are notable:
•
•
All the NEAFC closures lie within the proposed EBSAs.
The majority of the overall area covered by the ten proposed EBSAs is classed by NEAFC as ‘new fishing areas’
and thus subject to strict regulation. Exceptions that are not ‘new fishing areas’ include an existing fishing area
within the proposed EBSA 1 (Reykjanes Ridge), four within the proposed EBSA 3 (Mid-Atlantic Ridge north
of Azores), and a further four within the proposed EBSA 4 (Hatton–Rockall area).
The four major fisheries in the NEAFC Regulatory Area (herring, mackerel, blue whiting, and redfish) are pelagic trawl
fisheries and therefore unlikely to pose threats to seabirds, taxa on the OSPAR list of threatened and declining species, or
VMEs. In addition NEAFC regulations include:
•
•
A ban on the use of gillnet at depths greater than 200 m.
A ban on directed fisheries for 17 different species of deep-sea sharks.
ICES Advice 2013, Book 1
271
Figure 1.5.6.6.1
272
Map of the southern NEAFC Regulatory Area showing proposed EBSAs (Grey polygons; 1 = Reykjanes Ridge,
2 = Charlie-Gibbs Fracture Zone and Subpolar Frontal Zone, 3 = Mid-Atlantic Ridge north of the Azores, 4 =
Hatton–Rockall Plateau, 5 = Pedro Nunes and Hugo de Lacerda Seamounts, 6 = Northeast Azores–Biscay Rise,
7 = Evlanov Seamount, 8 = West of Azores). Existing NEAFC fishing areas are shown in white, NEAFC bottom
fishery closures in pink, and OSPAR High Seas MPAs in green.
ICES Advice 2013, Book 1
Table 1.5.6.6.1
Management measures adopted by NEAFC in each proposed EBSA.
NEAFC closed areas or
Rationale for NEAFC
fishing regulations in the
management measure
proposed area
Area 1. Reykjanes Ridge south of Iceland EEZ
1) Northern Mid-Atlantic
1,3,5) Protection of VME
Ridge (MAR)1
(cold-water corals).
2) Seasonal blue ling
2) Protection for
closure 2
spawning/aggregation
3)Existing fishing areas1
areas of blue ling.
4)New fishing areas1
NEAFC management regulations
1) Area closed to bottom trawling and fishing with static
gear, including bottom-set gillnets and longlines 2009–
2015.
2) This area is closed for fishing blue ling from 15
February to 15 April until 2016.
3) Deep-sea demersal fisheries regulations: Certain gears
are banned (gillnets) and actions against ghost fishing
and lost gear are in place.
4) Authorization to go to new fishing areas follows a
strict exploratory fishing protocol.
Area 2. Charlie-Gibbs Fracture Zone and Subpolar Frontal Zone of the Mid-Atlantic Ridge
Middle MAR1
Protection of VME (coldArea closed to bottom trawling and fishing with static
water corals).
gear, including bottom set gillnets and long-lines 20092015, including Charlie-Gibbs Fracture Zone and the
Subpolar frontal zone.
Area 3. Mid-Atlantic Ridge north of the Azores
1)Southern MAR; Altair
Protection of VME (cold1) Area closed to bottom trawling and fishing with static
Seamount, Antialtair
water corals).
gear, including bottom-set gillnets and longlines 2009–
Seamount1
2015.
2)Existing fishing areas1
2) Deep-sea demersal fisheries regulations: Certain gears
3)New fishing areas1
are banned (gillnets) and actions against ghost fishing
and lost gear are in place.
3) Authorization to go to new fishing areas follows a
strict exploratory fishing protocol.
Area 4. The Hatton and Rockall banks and Hatton–Rockall Basin
1) Rockall Haddock Box3
1) Haddock Box closed to
1) NEAFC has banned bottom trawling in this area.
2) Hatton4
protect juvenile haddock.
2–7) Area closed to bottom trawling and fishing with
2–7) Protection of VME
3) West Rockall Mounds
static gear, including bottom-set gillnets and longlines
(corals, coral reefs, and
closure4
until 2015.
4) NW Rockall closure4
sponge grounds).
8) Deep-sea demersal fisheries regulations: Certain gears
5) SW Rockall closure4
7) Geomorphology.
are banned (gillnets) and actions against ghost fishing
6) Logachev Mounds
and lost gear are in place.
closure 4
9) Authorization to go to new fishing areas follows a
7) Edora Bank closure5
strict exploratory fishing protocol.
8) Existing fishing areas1
9) New fishing areas1
ICES Advice 2013, Book 1
273
NEAFC closed areas or
Rationale for NEAFC
NEAFC management regulations
fishing regulations in the
management measure
proposed area
Area 5. Around Pedro Nunes and Hugo de Lacerda Seamounts – IBA MAO3
Area 6. Northeast Azores–Biscay Rise – IBA MAO3
Area 7. Evlanov Seamount Region
Area 8. Northwest of Azores EEZ
Area 9. The Arctic Front – Greenland/Norwegian Seas
New fishing areas1
In most instances there is not enough research or
Observers shall collect data in
data to identify VMEs in “new fishing areas”. To
accordance with a Vulnerable
reduce risks to VMEs to a minimum these areas
Marine Ecosystem Data
are closed to normal commercial bottom fisheries
Collection Protocol.
under normal authorizations to fish from the
Contracting Parties of NEAFC.
Exploratory Bottom Fisheries Protocol. Vessels
authorized under this protocol must have an
observer on board.
Exploratory fishing provides an opportunity to
gather additional data on benthos and fish
communities using industry vessels, and under
strict controls on fishing.
Area 10. The Arctic Ice habitat – multiyear ice, seasonal ice, and marginal ice zone
This proposed area is outside of the NEAFC Regulatory Area.
The following measures can be found at http://neafc.org/measures:
6
7
8
9
10
Rec. na 2011 on regulating bottom fishing as amended by Rec. 12 2013.
Rec. 05 2013 Blue Ling seasonal closure.
Rec. 03 2013 Rockall Haddock.
Rec. 09 2013 Rockall Hatton VME closures.
Rec. 08 2013 Edora Bank VME closure.
International Commission for the Conservation of Atlantic Tuna (ICCAT)
ICCAT has recommendations to mitigate the bycatch of seabirds, turtles, and pelagic shark species, but there are no
specific spatial management measures relevant to the proposed EBSAs.
OSPAR
A range of measures have been adopted by the OSPAR Commission within the proposed EBSAs. These include legally
binding decisions, which have been used for the establishment of seven marine protected areas (MPAs) in areas beyond
national jurisdiction. Five of these lie within the proposed EBSAs. Two others lie outside the proposed EBSAs: the Milne
Seamount complex MPA in the southwest of the OSPAR Area and the Josephine Seamount High Seas MPA in the
southeast (Figure 1.5.6.6.1). For each MPA, OSPAR has also agreed recommendations for their management calling on
Contracting Parties to undertake certain management actions within the competence of OSPAR (Table 1.5.6.6.2).
In addition to these are three types of measures that are not spatially explicit and that apply across the OSPAR maritime
area in the Northeast Atlantic (Table 1.5.6.6.3). These include a series of recommendations for the protection and
conservation of threatened and/or declining species; a recommendation calling on Contracting Parties to specifically take
into account OSPAR’s Listed of species and habitats in the conduct of Environmental Impact Assessments; as well as a
code of conduct for undertaking marine research.
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Table 1.5.6.6.2
Measures adopted by the OSPAR Commission specific to proposed EBSAs.
Proposed area meeting
the EBSA criteria
Charlie-Gibbs Fracture
Zone and Subpolar
Frontal Zone of the MidAtlantic Ridge
Mid-Atlantic Ridge north
of the Azores
Table 1.5.6.6.3
•
•
•
•
•
•
•
•
•
•
•
•
Spatial management measures in place for specific sub-areas within the proposed
EBSA
(1.a) OSPAR Decision 2010/2 on the establishment of the Charlie-Gibbs South MPA
(1.b) OSPAR Recommendation 2010/13 on the management of the Charlie-Gibbs
South MPA
(2.a) OSPAR Decision 2012/1 on the establishment of the Charlie-Gibbs North High
Seas MPA
(2.b) OSPAR Recommendation 2012/1 on the management of the Charlie-Gibbs North
High Seas MPA
(1.a) OSPAR Decision 2010/6 on the establishment of the Mid-Atlantic Ridge north of
the Azores High Seas MPA
(1.b) OSPAR Recommendation 2010/17 on the management of the Mid-Atlantic Ridge
north of the Azores High Seas MPA
(2.a) OSPAR Decision 2010/3 on the establishment of the Altair Seamount High Seas
MPA
(2.b) OSPAR Recommendation 2010/14 on the management of the Altair Seamount
High Seas MPA
(3.a) OSPAR Decision 2010/4 on the establishment of the Antialtair Seamount High
Seas MPA
(3.b) OSPAR Recommendation 2010/15 on the management of the Antialtair Seamount
High Seas MPA
General management measures taken by the OSPAR Commission that are common to all proposed EBSAs.
OSPAR Code of Conduct for Responsible Marine Research in the Deep Seas and High Seas of the OSPAR
Maritime Area (Reference number: 2008-1)
OSPAR Recommendation 2010/5 on assessments of environmental impact in relation to threatened and/or
declining species and habitats
OSPAR Recommendation 2010/6 on furthering the protection and restoration of the common skate species
complex, the white skate, the angel shark, and the basking shark in the OSPAR Maritime Area
OSPAR Recommendation 2010/7 on furthering the protection and restoration of the Orange roughy
(Hoplostethus atlanticus) in the OSPAR Maritime Area
OSPAR Recommendation 2010/8 on furthering the protection and restoration of Lophelia pertusa reefs in the
OSPAR Maritime Area
OSPAR Recommendation 2010/9 on furthering the protection and restoration of coral gardens in the OSPAR
Maritime Area
OSPAR Recommendation 2011/2 on furthering the protection and conservation of the Ivory gull (Pagophila
eburnea)
OSPAR Recommendation 2011/3 on furthering the protection and conservation of the Little shearwater
(Puffinus assimilis baroli)
OSPAR Recommendation 2011/4 on furthering the protection and conservation of the Balearic shearwater
(Puffinus mauretanicus)
OSPAR Recommendation 2011/5 on furthering the protection and conservation of the Black-legged kittiwake
(Rissa tridactyla tridactyla)
OSPAR Recommendation 2011/6 on furthering the protection and conservation of the Roseate tern (Sterna
dougallii)
OSPAR Recommendation 2011/7 on furthering the protection and conservation of the Thick-billed murre
(Uria lomvia)
International Maritime Organization (IMO) and the London Convention
No spatially based measures have been introduced by IMO or the London Convention for Areas Beyond National
Jurisdiction in the Northeast Atlantic. Many general IMO measures (e.g. ballast water exchange protocols, disposal of
waste) will apply to these areas.
ICES Advice 2013, Book 1
275
International Seabed Authority (ISA)
According to UNCLOS ISA is the competent authority that regulates mining and mineral extraction in “The Area”
(http://www.isa.org.jm/en/scientific/exploration). A memorandum of understanding was signed between the OSPAR
Convention and the International Seabed Authority in June 2011 to facilitate consultation and sharing of data and
information of relevance, with a view to promoting and enhancing a better understanding and coordination of their
respective activities.
There are three types of deep-sea mineral resources that are of commercial interest: polymetallic nodules, polymetallic
sulphides, and cobalt-rich ferromanganese crusts. So far, ISA has only adopted the regulatory framework for the
exploration of deep-sea mineral resources, including very strict regulations to ensure full environmental impact
assessments are undertaken prior to any activity in “The Area”. The framework for the exploitation of these resources has
yet to be developed and adopted.
There are several areas in the Northeast Atlantic identified as having deposits of mineral resources of possible commercial
interest, but exploratory mining cannot commence without adoption of a management framework.
Arctic Council
In follow-up to a recommendation to identify areas of heightened ecological and cultural significance, a report is being
prepared for the Arctic Council’s Protection of the Arctic Marine Environment Working Group (PAME). If the areas are
agreed, it is recommended that Arctic states, where appropriate, should encourage implementation of measures to protect
these areas from the impacts of Arctic marine shipping, in coordination with all stakeholders and consistent with
international law.
National and European Union
At the national and EU levels, many relevant measures for the protection of areas have not been systematically reviewed
by ICES. Several of these measures implement more general international obligations, for instance under the Convention
on Trade in Endangered Species.
Sources
ICES. 2013a. Vulnerable deep-water habitats in the NEAFC Regulatory Area. In Report of the ICES Advisory
Committee, 2013, Section 1.5.5.1. ICES Advice, 2013, Book 1.
ICES. 2013b. Report of the Workshop to Review and Advise on EBSA Proposed Areas (WKEBSA), 27–31 May 2013,
Copenhagen, Denmark. In draft.
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1.5.6.7
Special Request, Advice September 2013
ECOREGION
General advice
SUBJECT
OSPAR/NEAFC special request on review and reformulation of four
EBSA Proformas
Advice summary
ICES provided advice to OSPAR and NEAFC in June 2013 (OSPAR/NEAFC special request on review of the results of
the Joint OSPAR/NEAFC/CBD Workshop on Ecologically and Biologically Significant Areas (EBSAs) (ICES Advice
2013 section 1.5.5.5).
Following discussion with OSPAR and NEAFC, ICES (using experts of the review group) agreed to reformulate and
revise four of the EBSAs and provide new updated maps.
The material consists of scientifically updated Proformas for the following EBSAs:
•
•
•
•
Mid-Atlantic Ridge North of the Azores and South of Iceland
Charlie-Gibbs Fracture Zone (and the Sub-Polar Front)
The Hatton and Rockall Banks and the Hatton-Rockall Basin
The Arctic Ice habitat – multiyear ice, seasonal ice – marginal ice zone
During the update on the Charlie-Gibbs Fracture Zone (CGFZ) it appeared that the Sub-Polar Front, which was included
in the previous version of the Proforma, could not be scientifically supported with the evidence to hand at the time and
was therefore excluded from the CGFZ Proforma. A short note explains the reasons and consequences for the exclusion.
•
Note on the Sub Polar Front.
The five documents are scientifically updated technical documents and appended to this advice.
ICES Advice 2013, Book 1
277
ANNEX 1
Draft Proforma: The Hatton and Rockall Banks and the Hatton-Rockall Basin
Presented by: The Joint OSPAR/NEAFC/CBD Scientific Workshop. Reviewed by an ICES expert group and
revised by Francis Neat and J. Murray Roberts.
Based on an original proposal submitted by: Dr David Billett and Dr Brian Bett (Deepseas Group, Ocean
Biogeochemistry and Ecosystems Department, NOC, UK), Prof. Philip Weaver (Seascape Consultants Ltd and National
Oceanography Centre, UK), Prof Callum Roberts and Ms Rachel Brown (Environment Department, University of York),
Dr Murray Roberts and Dr Lea-Anne Henry, (Centre for Marine Biodiversity and Biotechnology, School of Life
Sciences, Heriot-Watt University), Dr Kerry Howell and Dr Jason Hall-Spencer (Marine Biology and Ecology Research
Centre, Marine Institute, University of Plymouth); Dr Andrew Davies (School of Ocean Sciences, Bangor University);
Dr Bhavani Narayanaswamy (Scottish Association for Marine Science, Oban), Prof. Monty Priede (OceanLab, University
of Aberdeen); Dr David Bailey (Division of Environmental and Evolutionary Biology, University of Glasgow); Prof.
Alex Rogers (University of Oxford) and Mr Ben Lascelles (Global Seabird Programme, Bird Life International)
Abstract
The Hatton and Rockall Banks, associated slopes and connecting basin, represent offshore bathyal habitats between 200
to 1500 m that constitute a unique and prominent feature of the NE Atlantic. The area has high habitat heterogeneity and
supports a wide range of benthic and pelagic species and ecosystems. There is significant fishing activity in the area,
including bottom trawling, long-lining, and midwater fisheries.
Introduction
The Hatton and Rockall Banks are large isolated geomorphological features in the NE Atlantic. Formed from continental
crust, they span depths from c. 200 to 2000m. The banks are linked by the Hatton-Rockall Basin at a depth of
approximately 1300 m which has particular geomorphological features and habitats. The gently sloping banks and the
basin provide a contrasting geological setting to the tectonically active Mid-Atlantic Ridge to the west and the generally
steeper slopes of the European continental margin to East. The banks encompass a large depth range with strong
environmental gradients (e.g. temperature, pressure, and food availability) that give rise to a high diversity of species and
habitats (Billett, 1991; Bett, 2001; Howell et al., 2002; Davies et al. 2006; Roberts et al. 2008; Howell et al., 2009; Howell
et al. 2010). Environmental heterogeneity is positively correlated with biological diversity at a variety of scales (Menot
et al. 2010) as indicated by significantly elevated levels of species change across space (in areas such as Hatton Bank
(Roberts et al. 2008).
Changes in pressure and temperature have significant effects on the biochemistry of species, influencing cell membrane
structure and enzyme characteristics (Gage and Tyler, 1991). In general, each species is adapted to a particular range of
environmental conditions. Each may occur over a depth range of about 500 m, but the depths where any particular species
is abundant, and therefore able to form viable populations, is generally limited to a much more restricted depth range of
100 to 200 m (Billett, 1991; Howell et al., 2002). There is evidence that such depth-related effects promote speciation
(Howell et al., 2004). In addition, the progressive decrease in organic matter availability with increasing depth (with some
patchiness depending on geomorphology) leads to a reduction of carnivores and an increase in detritus feeders (Billett,
1991). Taken together such environmental changes lead to a continuous sequential change in species composition with
depth, and biological community characteristics that are radically different to those known in shelf seas.
The area is influenced by a number of different water masses and there is considerable interaction between the topography
and physical oceanographic processes, in some areas focusing internal wave and tidal energy (Ellett et al. 1986) which
results in strong currents and greater mixing. This may give rise to highly localized and specialised biological
communities such as sponge aggregations and coral gardens. The mixing of Arctic and Atlantic water in the North of the
area means that species from both ecosystems are represented causing enhanced species diversity.
The Rockall Bank supports shallow demersal fisheries targeting haddock, gurnard and monkfish (Neat & Campbell 2010).
The slopes and the Hatton Bank are target areas for deep-water bottom fisheries for Ling (Molva molva), Blue Ling
(Molva dypterygia), Tusk (Brosme brosme), Roundnose Grenadier (Coryphaenoides rupestris) and Black Scabbardfish
(Aphanopus carbo). In the past deepwater sharks were also caught in the area, but this is now prohibited. A wide variety
of other fish species are also taken as by-catch (Gordon et al., 2003; Large et al., 2003; ICES 2010). Some of the deepwater target species have characteristic low productivity and extended generation times. Deep-water fisheries have
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significant effects not only on target fish species, but also on the benthic fauna (Le Guilloux et al., 2009; Clark et al.
2010).
Major wide-ranging Northeast Atlantic epipelagic fish stocks, e.g. mackerel and blue whiting, use the Hatton-Rockall
area for parts of their life cycle and are targeted by international fisheries. The slopes of the banks and channels between
the banks have a diverse bathy- and mesopelagic fish community sustained by the zooplankton production in the
epipelagic zone. The pelagic communities are similar to, and probably extensions of, those in adjacent oceanic waters
along the European continental margin.
Some invertebrate species, such as cold-water corals and sponges, provide important structural habitat heterogeneity.
These habitats are highly susceptible to physical damage and may take hundreds, if not thousands, of years to reform
(Hall-Spencer et al. 2002; Roberts et al. 2009; Söffker et al., 2011).
Current fisheries control measures on Hatton and Rockall Bank have focused mainly on the protection of corals (HallSpencer et al., 2009) and sponges (ICES 2013).
There is no evidence currently that the seabed at depth greater than 1500 m in the area is significantly different from
comparable depths in the rest of the NE Atlantic. The majority of the features considered here occur at depths shallower
than 1500 m and this therefore forms an appropriate delimitation of the EBSA.
Location
The EBSA would comprise the seabed and pelagic zones shallower than 1500 m above the Rockall and Hatton Banks
and the adjoining Hatton-Rockall Basin. This extends into adjacent EEZs, but the current proposal refers to the ABNJ
only. The area beyond national jurisdiction lies wholly within regions under consideration by the Commission on the
Limits of the Continental Shelf.
Feature description
Benthic and pelagic communities to depths of 1500 m in and around the Hatton and Rockall Banks and Basin. Seabed
communities include cold-water coral formations and sponge aggregations. Geomorphologically complex seabed types
include rocky reefs, carbonate mounds, polygonal fault systems and sedimentary slopes, slides and fans. Pelagic
communities include those inhabiting bathy-, meso- and epi-pelagic zones, including zooplankton, fish, cetaceans, turtles
and seabirds.
1. Benthic and benthopelagic communities
Cold-water coral
Observations in the early 1970s found cold-water coral communities on the Rockall Bank down to a depth of 1,000 m
(Wilson, 1979a). Thickets of Lophelia pertusa occurred principally at depths between 150-400m 21. Large coral growth
features have recently (2011) been discoveredto be still present on the northern Rockall Bank (Huvenne et al., 2011,
Roberts et al. 2013). Bottom-contact fishing can result in significant adverse impacts to these habitats.
Frederiksen et al. (1992) reported a high diversity of corals on the northern Hatton Bank, including Paragorgia,
Paramuricea, Isididae and Antipatharia as well as the scleractinians L. pertusa and M. oculata. Since these observations
further records of coral frameworks have been noted throughout the Rockall, Hatton area, including the Logachev Mounds
and the Western Rockall Bank Mounds (Kenyon et al., 2003; Roberts et al., 2003; Narayanaswamy et al., 2006; Howell
et al., 2007; Durán Muñoz et al. 2009).
Recent surveys identified many areas that contained the cold-water coral L. pertusa throughout the Rockall and Hatton
Banks (Narayanaswamy et al., 2006; Howell et al., 2007; Roberts et al. 2008; Durán Muñoz et al. 2009). Several areas
on the Hatton Bank contained pinnacles and mounds with extensive biogenic structures including areas of coral rubble
around the flanks of the coral mounds. Coral frameworks are known from the Hatton Bank (Durán Muñoz et al. 2009),
and are predicted to occur over focused regions of the Hatton Bank (Howell et al., 2011). Geophysical evidence suggests
that these have formed by successive coral growth and sedimentation episodes, as in other regions (Roberts et al., 2006),
forming coral carbonate mounds (Roberts et al. 2008). Single and clustered coral carbonate mounds have also been
discovered on the southeast of Rockall Bank. These structures are comprised mostly of L. pertusa and can reach heights
of 380 m in water depths of between 600-1000 m (Kenyon et al., 2003; Mienis et al., 2006; Mienis et al., 2007).
21
http://www.lophelia.org/lophelia/case_4.htm
ICES Advice 2013, Book 1
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Cold-water coral frameworks have been reported to support over 1,300 species in the Northeast Atlantic, some of which
have yet to be described (Roberts et al., 2006). New species and associations have been reported recently (e.g. Myers &
Hall-Spencer 2007; Le Guilloux et al., 2010; Söffker et al. 2011). The corals may provide an important habitat for certain
fish species (Fosså et al., 2002; Söffker et al. 2011; Henry et al 2013), including commercial species Sebastes sp., Molva
molva, Brosme brosme, Anarhichas lupus and Pollachius virens (Mortensen et al., 1995; Freiwald, 2002; Hall-Spencer
et al., 2002). Pregnant Sebastes viviparus may use the reef as a refuge or as a nursery ground to raise their offspring
(Fosså et al., 2002) as recently observed on the northern Rockall Bank (Huvenne et al., 2011, Roberts et al. 2013). As
well as living reefs, dead coral framework and coral rubble provide a structural habitat. Jensen and Frederiksen (1992)
collected Lophelia and found 256 species; a further 42 species were identified amongst coral rubble.
There has been only limited research into linkages between coral and other deep-water ecosystems. Compared to the
south-eastern US and Gulf of Mexico, molecular research has shown that northeastern Atlantic populations of L. pertusa
are moderately differentiated (Morrison et al. 2011) and form distinct subpopulations, but also that Rockall Bank corals
show some genetic similarity to those occurring on the New England Seamounts indicating some degree of connectivity
(Morrison et al. 2011). Lophelia pertusa exhibits high levels of inbreeding through asexual reproduction at several sites
in the NE Atlantic, suggesting a high incidence of self-recruitment in local populations (Le Goff-Vitry and Rogers, 2005).
Further molecular studies are required in local areas to gauge the importance of the Rockall and Hatton Banks in the life
history of regional coral populations.
In summary the cold-water corals fit the following EBSA criteria:
Uniqueness or rarity
•
Large areas of cold-water corals and sponges have been reported in the area. Some of these have been destroyed
by demersal trawling, but in certain areas, e.g. SW Rockall Bank, extensive patches of coral framework still exist.
Special importance for life-history stages
•
Cold-water corals and areas of natural coral rubble provide highly diverse habitats
Importance for threatened, endangered or declining species/habitats
•
•
The cold-water corals and natural rubble contain very large numbers of invertebrate species including giant
protozoans on nearby sedimentary habitats (xenophyophores), vase shaped white sponges, actiniarians,
antipatharian corals, hydroids, bryozoans, asteroids, ophiuroids, echinoids, holothurians and crustaceans.
The distribution of cold-water coral has been severely reduced in the area over the last 30 years
Vulnerability, fragility, sensitivity, or slow recovery
•
•
There is a high diversity of corals, including bamboo coral (Isididae), black coral (Antipatharia) as well as the reef
forming stony corals (Scleractinia), though some of these may now be reduced in distribution occurring in patches.
Cold-water coral habitats are easily impacted and recover very slowly, if at all.
Biological diversity
•
Cold-water corals provide diverse habitats for other invertebrates and fish.
Sediment communities
The Hatton and Rockall Banks support many different habitats each with their own depth-related species assemblages
(Narayanaswamy et al., 2006; Howell et al., 2007; Roberts et al. 2008; Howell et al., 2009). Local seabed morphology
in this region is ultimately controlled by hydrography and oceanography (Due et al. 2006; Sayago-Gil et al. 2010), which
creates heterogeneity in sediment types including mud, exposed bedrock, fine sediments, living coral framework and
coral debris that – this habitat heterogeneity has a major influence on species diversity and turnover (Roberts et al. 2008).
A great variety of large invertebrate fauna (megafauna) occur in this region including giant protozoans (xenophyophores),
vase shaped white sponges, actiniarians, antipatharian corals, hydroids, bryozoans, asteroids, ophiuroids, echinoids,
holothurians and crustaceans (Narayanaswamy et al., 2006; Howell et al., 2007; Roberts et al. 2008). Large mega-infauna
such as echiuran worms are evident from observations of their feeding traces. Little is known, however, of the smaller
fauna living within the sediment. The Hatton-Rockall Basin is known to host a particular geomorphology known as a
polygonal fault system (Berndt et al 2012). The faults in the Hatton-Rockall Basin have surface expression, i.e. a network
of interlinked channels across the level seafloor. These fault structures were confirmed again in 2011 (Huvenne et al.,
2011). The flanks of the gullies appear to support extensive, dense aggregations of mixed species sponge communities.
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A key interest / conservation concern in such a geological setting would be the occurrence of cold-seep communities.
Large carbonate blocks were encountered that were likely formed as a result of seafloor fluid escape. In 2012 the first
evidence of an active cold-seep ecosystem in the area was suggested by the collection of chemosynthetic bivalves and
polychaete worms (ICES 2013) on the eastern margin of Hatton-Rockall Basin at a depth of 1200 m. The species are new
to science and suggest there is a lot still to learn of the seafloor and ecology of the Hatton and Rockall Banks.
The megafauna on the Hatton and Rockall Banks are largely species known from the wider NE Atlantic continental
margin (Gage et al. 1983; Gage et al., 1985; Mauchline et al., 1986; Harvey et al., 1988; Rice et al., 1991). These studies
focused on sedimented areas within the EEZs of the UK and Ireland and provide a lot of information on the life history
characteristics of the species including information on growth and reproduction. Apart from some species that produce
small eggs (indicative of planktotrophic development) in a seasonal cycle, most species conform to the life history
characteristics typical of the deep sea of larger egg size, lower fecundity and greater generation times (Gage and Tyler,
1991). This is an adaptation to the low food input to the deep sea, which leads to the rapid decrease in biomass with
increasing depth (Lampitt et al., 1986; Wei et al., 2010). Fauna adapt to lower food availability in the deep sea by a
number of trade-offs, one of which is a reduction in reproductive effort and longer generation times. The majority of
species, therefore, are highly susceptible to repeated physical disturbance.
In summary the sediment communities fit the following EBSA criteria:
Uniqueness or rarity
•
•
The area has considerable environmental heterogeneity, and therefore biological diversity, as a result of its large
depth range and strong environmental gradients. Habitat-forming sessile benthic communities, such as those of
giant protozoans and sponges, are common.
The area of polygonal faults may be a unique seabed feature and the presence of newly described chemosynthetic
bivalves and polychaete worms suggests the area may have unique communities.
Importance for threatened, endangered or declining species/habitats
•
The area comprises a patchwork of habitats with species changing consistently with both habitat type and
increasing to depths of 1500 m. Some habitats are threatened by direct impacts (e.g. trawling).
Vulnerability, fragility, sensitivity, or slow recovery
•
Many of the species have reproductive cycles with long generation times leading to very slow and episodic
recoveries following human impact. Most deep-sea species are particularly susceptible to degradation and depletion
by human activity.
Biological productivity
•
There are localised areas of concentrated production depending on geomorphology and hydrography, but little
evidence that the area has an enhanced productivity relative to other areas.
Biological diversity
•
Benthic and pelagic communities occupy all depths in and around the Hatton and Rockall Banks and Basin. Seabed
communities include cold-water corals and sponge aggregations. Seabed geomorphology is diverse with examples
of rocky reefs, carbonate mounds, polygonal fault systems, and steep and gentle sedimentary slopes. This high
habitat heterogeneity supports a high number of species and diverse communities.
Demersal fish
The deep-water fish of the NE Atlantic continental margin are generally well-known following comprehensive and
extensive surveys of the region (e.g. Gordon & Duncan, 1985; Merrett et al., 1991; Mauchline et al. 1986 and Rice et al.
1991). Species of commercial importance are reviewed by Gordon et al. (2003) and Large et al. (2003) and for fish
associated with cold-water corals by Söffker et al. (2011). Fish species diversity increases to depths of approx. 1500 m
on the continental slopes and declines thereafter (Campbell et al 2011). The shallow water fish assemblage on Rockall
can be described as an impoverished sub-set of that found in adjacent continental shelf areas, but one that has a
significantly different community composition (Neat & Campbell 2010). Recent surveys have found that the western
slope of the Rockall Bank has a slightly different fish assemblage than the adjacent European slope with several species
of a more southern affinity present (F. Neat unpublished data). Blue ling is known to spawn in a few locations on Rockall
bank and at Hatton bank (Large et al 2008).
ICES Advice 2013, Book 1
281
The detailed sampling in the Porcupine Seabight in the 1970s and 1980s took place before the start of deep-water
commercial fishing. More recent sampling of the same area in the 1990s and 2000s can be used to compare fish
communities before and after bottom trawling (Bailey et al. 2009). These data show that over 70 fish species have been
impacted by the fishing activity, of which only 4-5 are target commercial species. The area impacted is up to 2.5 times
larger than the area fished because the home range of many the fish extends into considerably deeper waters. In the past
decade, however, there is evidence that this initial steep decline in abundance has been halted, at least in one of the major
groups of fishes, the grenadiers (Neat & Burns 2010). At the northern limits of the area where Arctic water masses mix
with Atlantic water cold-water species such as Greenland Halibut and Roughhead Grenadier are present adding to the
diversity of species in the area.
In summary the demersal fish fit the following EBSA criteria:
Vulnerability, fragility, sensitivity, or slow recovery
•
Many of the deep demersal fish have very slow recovery times as a result of their slow reproductive rate compared
to pelagic fish.
2. Pelagic communities (plankton, nekton, birds)
Fish: Mackerel, blue whiting and other wide-ranging pelagic fish such as epipelagic sharks and tuna-like species use the
area during parts of their life-cycle, for feeding or as migration corridors. For blue whiting the slope area is used as a
spawning area. Mackerel eggs and larvae from spawning areas further south drift through the area.
Cetaceans: Phocoena phocoena have been observed over the shallower parts of Rockall Bank, but It is unlikely that the
area is of particular importance for the species. Limited numbers of the endangered Blue whale (Balaenoptera musculus)
and the critically endangered northern right whale (Eubalaena glacialis) have also been observed in this area (Cronin and
Mackey, 2002; Hammond et al., 2006).
Seabirds: Analyses of satellite tracking data hosted at www.seabirdtracking.org (Table 1) found the area to be used by
multiple species through the year. The site is used by Manx Shearwaters (Puffinus puffinus) during the breeding season
(Apr-Sept) from Iceland and UK colonies. From September until November tracked individuals of Cory’s Shearwater
(Calonectris diomedea) from 3 colonies, Sooty Shearwater (Puffinus griseus), Fea’s Petrel (Pterodroma feae) and Zino’s
Petrel (Pterodroma madeira) used the area. Studies of tracked Atlantic Puffin (Fratercula arctica) from Skomer and Isle
of May colonies found the site to be important during the overwintering phase (Aug-Apr) (Harris et al. 2010, Guilford et
al. 2011). In addition to tracking data, at-sea survey data confirms many more species within the area (e.g. Cronin and
Mackey, 2002).
Feature condition, and future outlook
Demersal fish have been targets of extensive fisheries for decades, expanding primarily in the latter half of the 1980s.
Although satisfactory stock assessments were seldom achieved, the probable declines in abundance and vulnerability of
many of the target species have been reflected in advice from ICES for many years (ICES 1996 onwards, Large et al.,
2003). A range of management actions by NEAFC and relevant coastal states have been implemented to reduce fishing
effort and facilitate recovery of target species and some associated by-catch species. A similar range of measures applies
to species inhabiting the shallowest areas, e.g. haddock.
Epipelagic species such as mackerel and blue whiting, and large pelagic sharks and tuna-like species occurring in the area
straddle between ABNJ and several EEZs and the fisheries are managed by relevant coastal states, NEAFC and ICCAT.
Cetaceans are managed by the IWC. The management is based on recurrent stock assessments by ICES and other advisory
bodies.
Records of the physical impact of deep-water trawling west of Scotland extend back to the late 1980s (Roberts et al.,
2000; Gage et al., 2005) and studies using VMS data show that fishing activity potentially affects much of the HattonRockall area (Hall-Spencer et al. 2009; Benn et al. 2010). Damage may occur to structural species such as corals and
sponges, which may take hundreds to thousands of years to recover (Hall-Spencer et al., 2002; Davies et al. 2007; Roberts
et al., 2009; Hogg et al. 2010).
A recent survey (2011) has documented extensive destruction of coral framework on the northern Rockall Bank (Huvenne
et al. 2011) in waters adjacent to the area currently being described. This expedition also encountered evidence of trawling
impact on the megafauna of open sedimented areas, with photographic surveys in the area of the 'Haddock Box' (Rockall
Bank) showing frequent occurrence of physically damaged holothurians - thought to be net escapees or discarded by282
ICES Advice 2013, Book 1
catch. Cold seep communities are vulnerable to trawling impacts; they are typically highly localised and are of a relatively
small scale such that they could be eliminated by a single trawl. Cold seeps are OSPAR priority habitats for which there
are considerable concerns regarding the effects of bottom trawling (van Dover et al. 2011a, b).
Some of the benthic communities of the Hatton and Rockall Banks have already been significantly affected by deep-water
fishing (ICES WGDEC, 2007). The effects on deep-water fish may extend to waters deeper than those utilised by trawl
fisheries (Bailey et al., 2009). Broad-scale multibeam surveys have revealed a diverse range of geomophological features
and sediment types on Hatton Bank (Jacobs and Howell, 2007; Stewart and Davies, 2007; MacLachlan et al., 2008;
Sayago-Gil et al., 2010). These physical environment maps, coupled with targeted biological surveys have resulted in the
production of biological habitat maps for the region (Howell et al., 2011) which highlight the range and diversity of noncoral seabed features present in the area.
Assessment against CBD EBSA Criteria
Table 1.
Relation of each of the CBD criteria to the proposed area relating to the best available science. Note that a
candidate EBSA may qualify on the basis of one or more of the criteria, the boundaries of the EBSA need
not be defined with exact precision.
CBD EBSA
Criterion
Description
The area contains either (i) unique (“the only one of its
kind”), rare (occurs only in few locations) or endemic
species, populations or communities, and/or (ii) unique,
rare or distinct, habitats or ecosystems; and/or (iii) unique
or unusual geomorphological or oceanographic features
Explanation for ranking
Uniqueness or
rarity
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
Know
High
X
•
The area has considerable environmental heterogeneity, and therefore biological diversity, as a result of its large depth
range and strong environmental gradients. Habitat-forming sessile benthic communities, such as those of giant protozoans
and sponges, are common.
•
Large areas of cold-water corals and sponges have been reported in the area. Some of these have been destroyed by
demersal trawling, but some areas of large coral frameworks still exist.
•
An area of polygonal faults may be a unique seabed feature and the recent discovery of cold-seep species that are new to
science suggests the area is very likely to be unique.
Areas that are required for a population to survive and
Special
X
thrive
importance for
life-history
stages of species
Explanation for ranking
•
•
Cold-water corals and areas of natural coral rubble provide highly diverse habitats
Parts of the Hatton-Rockall area are important as spawning areas for blue whiting, and the area is used as a corridor for a
range of migrating species including turtles.
Area containing habitat for the survival and recovery of
Importance for
X
endangered, threatened, declining species or area with
threatened,
significant assemblages of such species
endangered or
declining species
and/or habitats
Explanation for ranking
•
•
•
The cold-water corals and natural rubble contain very large numbers of invertebrate species including giant protozoans
(xenophyophores), vase shaped white sponges, actiniarians, antipatharian corals, hydroids, bryozoans, asteroids,
ophiuroids, echinoids, holothurians and crustaceans.
The distribution of cold-water coral has been severely reduced in the area over the last 30 years
The area comprises a patchwork of habitats with species changing consistently with both habitat type and increasing depth.
Some habitats are threatened by direct impacts (e.g. trawling), others may suffer indirectly e.g. through the creation of
sediment plumes by impacts of fishing gear in sensitive areas.
ICES Advice 2013, Book 1
283
Areas that contain a relatively high proportion of sensitive
Vulnerability,
habitats, biotopes or species that are functionally fragile
fragility,
(highly susceptible to degradation or depletion by human
sensitivity, or
activity or by natural events) or with slow recovery
slow recovery
Explanation for ranking
•
•
•
•
X
There is a high diversity of corals, including bamboo coral (Isididae), black coral (Antipatharia) as well as the reef forming
stony corals (Scleractinia), though some of these may now be reduced in distribution occurring in patches.
Cold-water coral habitats are easily impacted and recover very slowly, if at all
Many of the species have reproductive cycles with long generation times leading to very slow and episodic recoveries
following human impact. Most deep-sea species are particularly susceptible to degradation and depletion by human
activity and natural events.
Many of the demersal fish have very slow recovery times as a result of their slow reproductive rate compared to pelagic
fish. Stocks have already been diminished in some areas.
Area containing species, populations or communities with
Biological
comparatively higher natural biological productivity
productivity
Explanation for ranking
X
• While pelagic organisms may be more concentrated over the banks in the area, there is little evidence to suggest overall
enhanced productivity of the area.
Area contains comparatively higher diversity of
Biological
X
ecosystems, habitats, communities, or species, or has
diversity
higher genetic diversity
Explanation for ranking
•
•
•
Benthic and pelagic communities occupy all depths in and around the Hatton and Rockall Banks and Basin. Seabed
communities include cold-water corals, rocky reefs, carbonate mounds, polygonal fault systems, sponge aggregations,
steep and gentle sedimented slopes.
The Hatton and Rockall Banks and the Hatton-Rockall Basin have a high habitat heterogeneity that supports diverse
seabed communities.
Cold-water corals provide diverse habitats for other invertebrates and fish.
References
Bailey, D.M., Collins, M.A., Gordon, J.D.M., Zuur, A.F. & Priede, I.G. (2009) Long-term changes in deep-water fish
populations in the northeast Atlantic: a deeper reaching effect of fisheries? Proc. Roy. Soc. Lond. B. 276, 19651969
Benn, A.R., Weaver, P.P.E, Billett, D.S.M., van den Hove, S., Murdock, A.P., Doneghan, G.B. & Le Bas, T. (2010).
Human Activities on the Deep Seafloor in the North East Atlantic: An Assessment of Spatial Extent. PLoS One
5(9): e12730. doi:10.1371/journal.pone.0012730.
Berndt, C, Jacobs, C. L., Evans, A. J., Gay, A., Elliot, G., Long, D. and Hitchen, K. (2012) Kilometre-scale polygonal
seabed depressions in the Hatton Basin, NE Atlantic Ocean: Constraints on the origin of polygonal faulting
Marine Geology, 332/334 . pp. 126-133. DOI 10.1016/j.margeo.2012.09.013.
Bett, B.J. (2001) UK Atlantic Margin Environmental Survey: introduction and overview of bathyal benthic ecology. Cont.
Shelf Res. 21, 917-956.
Billett, D.S.M. (1991) Deep-sea holothurians. Oceanogr. mar. Biol. Ann. Rev. 29, 259-317.
Campbell, N. et al. 2010. Taxonomic indicators of deep water demersal fish community diversity on the Northeast
Atlantic continental slope. ICES J. Mar. Sci. 68, 365-378.
Clark M.R., Rowden A.A., Schlacher T., Williams A., Consalvey M., Stocks K.I., Rogers A.D., O'Hara T.D., White M.,
Shank T.M. & Hall-Spencer J.M. (2010) The ecology of seamounts: structure, function and human impacts.
Annu. Rev. Mar. Sci. 2, 253-278.
Costello, M.J., McCrea, M., Freiwald, A., Lundälv, T., Jonsson, L., Bett, B.J., Van Weering, T.C.E., De Haas, H., Roberts,
J.M. & Allen, D. (2005) Role of cold-water Lophelia pertusa reefs as fish habitat in the NE Atlantic. In: Freiwald,
A., Roberts, J.M. (Eds.), Cold-water Corals and Ecosystems. Springer-Verlag, Berlin Heidelberg, pp. 771-805.
Cronin, M., Mackey, M. (2002) Cetaceans and Seabirds of the Hatton-Rockall Region, Cruise Report of the Geological
Survey of Ireland May 2002.
Davies, A.J., Narayanaswamy, B.E., Hughes, D.J. & Roberts, J.M. (2006) An introduction of the benthic ecology of the
Rockall-Hatton Area (SEA 7). Scottish Association for Marine Science, Oban, p. 94.
http://www.offshoresea.org.uk/
Davies, A.J., Wisshak, M., Orr, J.C. & Roberts, J.M. (2008) Predicting suitable habitat for the cold-water coral Lophelia
pertusa (Scleractinia). Deep-Sea Res. I 55, 1048-1062.
Davies. A., Roberts. J.M. & Hall-Spencer, J.M. (2007) Preserving deep-sea natural heritage: emerging issues in offshore
conservation and management. Biol. Cons. 138, 299-312.
284
ICES Advice 2013, Book 1
Due, L., van Aken. H.M., Boldreel. L.O. & Kuijpers, A. (2006) Seismic and oceanographic evidence of present-day
bottom-water dynamics in the Lousy Bank–Hatton Bank area, NE Atlantic. Deep-Sea Research I53:1729-1741
Durán Muñoz, P., Sayago-Gil, M., Cristobo, J., Parra, S., Serrano, A., Díaz del Rio, V., Patrocinio, T., Sacau, M., Murillo,
F.J., Palomino, D. & Fernández-Salas, L.M. (2009) Seabed mapping for selecting cold-water coral protection
areas on Hatton Bank, Northeast Atlantic. ICES J. Mar. Sci. 66, 2013-2025
Ellett, D.J., Edwards, A. & Bowers, R. (1986) The hydrography of the Rockall Channel – an overview. Conference
Proceedings Symposium on the Oceanography of the Rockall Channel, Edinburgh (UK), 27-29 Mar 1985.
Fosså, J.H., Mortensen, P.B. & Furevik, D.M. (2002) The deep-water coral Lophelia pertusa in Norwegian waters:
distribution and fishery impacts. Hydrobiologia 471, 1-12.
Frederiksen, R., Jensen, A. & Westerberg, H. (1992) The distribution of the scleractinian coral Lophelia pertusa around
the Faeroe Islands and the relation to internal tidal mixing. Sarsia 77, 157-171.
Freiwald, A. (2002) Reef-forming cold-water corals. In: Wefer, G., Billett, D., Hebbeln, D., Jorgensen, B.B., Schluter,
M., Van Weering, T. (Eds.), Ocean Margin Systems. Springer-Verlag Berlin Heidelberg, Berlin, pp. 365-385.
Gage, J.D. & Tyler, P.A. (1991) Deep-Sea Biology. A Natural History of Organisms at the Deep-Sea Floor. Cambridge
University Press. 504pp.
Gage, J.D., Billett, D.S.M., Jensen, M. & Tyler, P.A. (1985) Echinoderms of the Rockall Trough and adjacent areas. 2.
Echinoidea and Holothurioidea. Bull. Br. Mus. Nat. Hist. (Zool.), 48, 173-213.
Gage, J.D., Pearson, M., Clark, A.M., Paterson, G.L.J. & Tyler, P.A. (1983) Echinoderms of the Rockall Trough and
adjacent areas. 1. Crinoidea, Asteroidea and Ophiuroidea. Bull. Br. Mus. nat. Hist. (Zool.) 45, 263-308.
Gage, J.D., Roberts, J.M., Hartley, J.P. & Humphery, J.D. (2005) Potential impacts of deepsea trawling on the benthic
ecosystem along the Northern European Continental Margin: A review. In: Barnes, P.W., Thomas, J.P. (Eds.),
Benthic Habitats and the Effects of Fishing. American Fisheries Society, Bethesda, Maryland, pp. 503-517.
Gordon, J. D. M., O. A. Bergstad, I. Figueiredo, and G. Menezes. 2003. Deep-water Fisheries of the Northeast Atlantic:
I. Description and Current Trends. J. Northw. Atl. Fish. Sci. 31: 137-150.
Gordon, J.D.M. & Duncan, J.A.R. (1985) The ecology of the deep-sea benthic and benthopelagic fish on the slopes of the
Rockall Trough, northeastern Atlantic. Prog. Oceanogr. 15, 37-69.
Guilford, T., Freeman, R., Boyle, D., Dean, B., Kirk, H., Phillips, R.A., Perrins, C. (2011) A dispersive migration in the
Atlantic Puffin and its Implications for Migratory Navigation, Plos One, 6(7), e21336.
Hall-Spencer J.M., Allain V. & Fossa J.H. (2002) Trawling damage to Northeast Atlantic ancient coral reefs. Proc. Roy.
Soc. Lond. B. 269, 507-511.
Hall-Spencer, J.M., Tasker, M., Söffker, M., Christiansen, S., Rogers, S., Campbell, M. & Hoydal, K. (2009) The design
of Marine Protected Areas on High Seas and territorial waters of Rockall. Mar. Ecol. Prog. Ser. 397, 305-308.
Harris, M.P., Daunt, F., Newell, M., Phillips, R.A., Wanless, S. (2010) Wintering areas of Atlantic Puffins Fratercula
arctica from a North Sea colony as revealed by geolocation technology, Mar Biol, 157, 827-836
Harvey, R., Gage, J.D., Billett, D.S.M., Clark, A.M. and Paterson, G.L.J. (1988) Echinoderms of the Rockall Trough and
adjacent areas. 3. Additional records. Bull. Br. Mus. (Nat. Hist.) (Zool.), 54 (4), 153-198.
Henry, L-A. & Roberts, J.M. (2007) Biodiversity and ecological composition of macrobenthos on cold-water coral
mounds and adjacent off-mound habitat in the bathyal Porcupine Seabight, NE Atlantic. Deep-Sea Res I 54,
654-672
Hogg, M.M., Tendal, O.S., Conway, K.W., Pomponi, S.A., van Soest, R.W.M., Gutt, J., Krautter, M. & Roberts, J.M.
(2010) Deep-sea Sponge Grounds: Reservoirs of Biodiversity. UNEP-WCMC Biodiversity Series No. 32.
UNEP-WCMC, Cambridge, UK
Howell, K., Billett, D.S.M. & Tyler, P.A. (2002). Depth-related distribution and abundance of seastars
(Echinodermata:Asteroidea) in the Porcupine Seabight and Porcupine Abyssal Plain, N.E. Atlantic. Deep-Sea
Res. I 49, 1901-1920.
Howell, K.L. (2010) A benthic classification system to aid in the implementation of marine protected area networks in
the deep / high seas of the NE Atlantic. Biol. Cons. 143, 1041–1056.
Howell, K.L., Davies J.S., Jacobs, C., and Narayanaswamy B.E. (2007). Broadscale Survey of the Habitats of Rockall
Bank, and mapping of Annex I ‘Reef’ Habitat. Joint Nature Conservation Committee Report. No. 422, 165p.
Howell, K.L., Davies J.S. & Narayanaswamy, B.E.(2010). Identifying deep-sea megafaunal epibenthic assemblages for
use in habitat mapping and marine protected area network design. J. Mar. Biol. Ass. UK 90, 33-68 .
Howell, K.L., Davies, J.S., Hughes, D.J. & Narayanaswamy, B.E. (2007) Strategic Environmental Assessment / Special
Area for Conservation Photographic Analysis Report. Department of Trade and Industry, Strategic
Environmental Assessment Report, UK, p. 163. Unpublished report.
Howell, K.L., Holt, R., Pulido Endrino, I. & Stewart, H. (2011) When the species is also a habitat: comparing the
predictively modelled distributions of Lophelia pertusa and the reef habitat it forms. Biol. Cons.
Howell, K.L., Mowles S. & Foggo, A. (2010) Mounting evidence: near-slope seamounts are faunally indistinct from an
adjacent bank. Mar. Ecol. 31, 52-62.
Howell, K.L., Rogers, A., Tyler, P.A. & Billett, D.S.M. (2004). Reproductive isolation among morphotypes of the
cosmopolitan species Zoroaster fulgens (Asteroidea:Echinodermata). Mar. Biol. 144, 977-984.
Husebø, A., Nottestad, L., Fosså, J.H., Furevik, D.M. & Jorgensen, S.B. (2002) Distribution and abundance of fish in
deep-sea coral habitats. Hydrobiologia 471, 91-99.
ICES Advice 2013, Book 1
285
Huvenne, V.A.I. et al. (2011) RRS James Cook Cruise 60, 09 May-12 Jun 2011. Benthic habitats and the impact of human
activities in Rockall Trough, on Rockall Bank and in Hatton Basin. (National Oceanography Centre Cruise
Report, No. 04) Southampton, UK: National Oceanography Centre, Southampton, 133pp.
ICES (2007) Report of the Working Group on Deep-Water Ecology (WGDEC), 26–28 February 2007, ICES Cm
2007/aCE:01 Ref lRC. International Council for the Exploration of the Sea, Copenhagen, Denmark, 57pp.
ICES 2010. Report of the Working group on the Biology and Assessemnt of Deepwater Fisheries Resources. www.ices.dk
Jacobs, C.L., Howell, K.L. (2007) Habitat investigations within the SEA4 and SEA7 area of the UK continental shelf.
MV Franklin Cruise 0206, 03-23 Aug 2006. Research and Consultancy Report No. 24. National Oceanography
Centre, Southampton. UK. 95pp.
Jensen, A. & Frederiksen, R. (1992) The fauna associated with the bank-forming deep-water coral Lophelia pertusa
(Scleractinaria) on the Faroe Shelf. Sarsia 77, 53-69.
Kenyon, N.H., Akhmetzhanov, A.M., Wheeler, A.J., van Weering, T.C.E., de Haas, H. & Ivanov, M.K. (2003) Giant
carbonate mud mounds in the southern Rockall Trough. Marine Geology 195, 5-30.
Lampitt, R.S., Billett, D.S.M. & Rice, A.L. (1986) The biomass of the invertebrate megabenthos from 500 to 4100m in
the North East Atlantic. Mar. Biol. 93, 69-81.
Large, P. A., C. Hammer, O. A. Bergstad, J. D. M. Gordon, and P. Lorance. 2003. Deep-water Fisheries of the Northeast
Atlantic: II. Assessment and Management Approaches. J. Northw. Atl. Fish. Sci. 31: 151-163.
Le Goff-Vitry & M.C. & Rogers, A.D. (2005) Molecular ecology of Lophelia pertusa in the NE Atlantic. In: Freiwald,
A., Roberts, J.M. (Eds.). Cold-water Corals and Ecosystems. Springer-Verlag, Berlin Heidelberg, pp. 653-662.
Le Guilloux, E., Hall-Spencer, J.M., Söffker, M.K. & Olu-Le Roy, K. (2010) Association between the squat lobster
Gastroptychus formosus (Filhol, 1884) and cold-water corals in the North Atlantic. J. Mar Biol. Ass. UK 90,
1363-1369.
MacLachlan SE, Elliot GM, Parson LM (2008) Investigations of the bottom current sculpted margin of Hatton bank, NE
Atlantic. Mar. Geol. 253:170–184
Mauchline, J., Ellett, D.J., Gage, J.D., Gordon, J.D.M. & Jones, E.J.W. (1986) A bibliography of the Rockall Trough.
Conference Proceedings Symposium on the Oceanography of the Rockall Channel, Edinburgh (UK), 27-29 Mar
1985.
Menot, L., Sibuet, M., Carney, R.S., Levin, L.A., Rowe, G.T., Billett, D.S.M., Poore, G., Kitazato, H., Vanreusel, A.,
Galéron, J., Lavrado, H.P., Sellanes, J., Ingole, B. & Krylova, E. (2010) New Perceptions of Continental Margin
Biodiversity. In: McIntyre, A., (Ed). Chapter 5. Life in the World’s Oceans: Diversity, Distribution and
Abundance. Wiley-Blackwell. 79-101.
Merrett, N.R., Gordon, J.D.M., Stehmann, M. & Haedrich, R.L. (1991) Deep demersal fish assemblage structure in the
Porcupine Seabight (eastern North Atlantic): slope sampling by three different trawls compared. J. Mar. Biol,
Ass. UK 71, 329-358.
Mienis, F., de Stigter, H.C., de Haas, H. & van Weering, T.C.E. (2009) Near-bed particle deposition and resuspension in
a cold-water coral mound area at the Southwest Rockall Trough margin, NE Atlantic. Deep-Sea Res. I 56, 10261038.
Morrison, C., Ross, S., Nizinski, M., Brooke, S., Järnegren, J., Waller, R., Johnson, R. & King, T. (2011) Genetic
discontinuity among regional populations of Lophelia pertusa in the North Atlantic Ocean. Cons. Genetics 12,
713-729
Mortensen, P.B., Hovland, M., Brattegard, T. & Farestveit, R. (1995) Deep-water bioherms of the scleractinian coral
Lophelia pertusa (L) at 64 degrees N on the Norwegian Shelf – Structure and associated megafauna. Sarsia 80,
145-158.
Myers, A.A. & Hall-Spencer, J.M. (2004) A new species of amphipod crustacean, Pleusymtes comitari sp. nov.,
associated with Acanthogorgia sp. gorgonians on deep-water coral reefs off Ireland. J. Mar. Biol. Ass. UK 84,
1029-1032.
Narayanaswamy, B.E., Howell, K.L., Hughes, D.J., Davies, J.S., Roberts, J.M. & Black, K.D. (2006) Strategic
Environmental Assessment Area 7 Photographic Analysis Report. 13. Department of Trade and Industry,
Strategic Environmental Assessment Report, UK, p. 179. Unpublished report.
Neat, F.C. & Burns, F. 2010. Stable abundance, but changing size structure in grenadier fishes (Macrouridae) over a
decade (1998-2008) in which deepwater fisheries became regulated. Deep Sea Res. I. 57, 434-440.
Neat, F. & Campbell, N. 2010. Demersal fish diversity of the isolated Rockall plateau compared with the adjacent west
coast shelf of Scotland. Biol. J. Linn. Soc. Lond. 104, 138-147.
Penny, A.J., Parker, S.J. & Brown, J.H. (2009) Protection measures implemented by New Zealand for vulnerable marine
ecosystems in the South Pacific Ocean. Mar Ecol. Prog. Ser. 397, 341-354.
Pollock, C & Barton, C. 2006. Offshore seabirds in the SEA 7 area. A report to the UK Department of Trade and Industry.
Rice, A.L., Billett, D.S.M., Thurston, M.H. and Lampitt, R.S. (1991). The Institute of Oceanographic Sciences Biology
Programme in the Porcupine Seabight: background and general introduction. J. Mar. Biol. Ass. U.K., 71, 281310.
Roberts, J.M., Harvey, S.M., Lamont, P.A., Gage, J.D. & Humphery, J.D. (2000) Seabed photography, environmental
assessment and evidence for deep-water trawling on the continental margin west of the Hebrides. Hydrobiologia
441: 173-183
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Roberts, J.M. and shipboard party (2013) Changing Oceans Expedition 2012. RRS James Cook cruise 073 Cruise Report.
Heriot-Watt University. 224 pp.
Roberts, J.M., Henry, L-A., Long, D. & Hartley, J.P. (2008) Cold-water coral reef frameworks, megafaunal communities
and evidence for coral carbonate mounds on the Hatton Bank, north east Atlantic. Facies 54: 297-316
Roberts, J.M., Long, D., Wilson, J.B., Mortensen, P.B. & Gage, J.D. (2003) The cold-water coral Lophelia pertusa
(Scleractinia) and enigmatic seabed mounds along the north-east Atlantic margin: are they related? Mar. Poll.
Bull. 46, 7-20.
Roberts, J.M., Wheeler, A., Freiwald, A. & Cairns, S.D. (2009) Cold-water corals: The biology and geology of deep-sea
coral habitats. Cambridge University Press. 334pp.
Roberts, J.M., Wheeler, A.J. & Freiwald, A. (2006) Reefs of the deep: The biology and geology of cold-water coral
ecosystems. Science 213, 543-547.
Rogers, A.D. & Gianni, M. (2010) The implementation of the UNGA Resolutions 61/105 and 64/72 in the management
of deep-sea fisheries on the High Seas. Report of the Deep-Sea Conservation Coalition. International Programme
on the State of the Ocean, London, UK. 97pp.
Sayago-Gil M, Long D, Hitchen K, Díaz-del-Río V, Fernández-Salas LM, Durán-Muñoz P (2010) Evidence for currentcontrolled morphology along the western slope of Hatton Bank (Rockall Plateau, NE Atlantic Ocean). Geo-Mar.
Lett. 30, 99-111
Söffker, M., Sloman, K.A. & Hall-Spencer, J.M. (2011) In situ observations of fish associated with coral reefs off Ireland.
Deep-Sea Res. I 58, 818-825
Stewart, H A, and Davies, J S. 2007. Habitat investigations within the SEA7 and SEA4 areas of the UK continental shelf
(Hatton Bank, Rosemary Bank, Wyville Thomson Ridge and Faroe–Shetland Channel). British Geological
Survey Commercial Report, CR/07/051.
Tittensor, D.P., Baco-Taylor, A.R., Brewin, P., Clark, M.R., Consalvey, M., Hall-Spencer, J.M., Rowden, A.A.,
Schlacher, T., Stocks, K. & Rogers, A.D. (2009) Predicting global habitat suitability for stony corals on
seamounts. J. Biogeog. 36, 1111-1128
Van Dover, C., Smith CR, Ardron J, Dunn D, Gjerde K, Levin L, Smith S and the Dinard Workshop Contributors (2011a).
Uncharted waters: Placing deep-sea chemosynthetic ecosystems in reserve. Marine Policy 36, 378-381.
Van Dover, C., Smith CR, Ardron J, Dunn D, Gjerde K, Levin L, Smith S and the Dinard Workshop Contributors (2011b).
Environmental management of deep-sea chemosynthetic ecosystems: justification of and considerations for a
spatially-based approach. International Seabed Authority Technical Study 9. 29pp.
Vanreusel, A., Fonseca, G., Danovaro, R., et al. (2010) The contribution of deep-sea macrohabitat heterogeneity to global
nematode diversity. Mar. Ecol. 31, 66-77.
Wei, C-L. et al. (2010). Global Patterns and Predictions of Seafloor Biomass Using Random Forests. PLoS One 5 (12)
http://dx.plos.org/10.1371/journal.pone.0015323.
Wilson, J.B., (1979a) The distribution of the coral Lophelia pertusa (L.) [L. prolifera (Pallas)] in the North-East Atlantic.
J. Mar. Biol. Ass. UK 59, 149-164.
Wilson, J.B., (1979b) ‘Patch’ development of the deep-water coral Lophelia pertusa (L.) on Rockall Bank. J. Mar. Biol.
Ass. UK 59, 165-177.
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Maps and Figures
Figure 1
288
Map of the ABNJ area in the NE Atlantic with boundary of the Hatton-Rockall EBSA outlined in red. This
boundary approximates the 1500 m contour.
ICES Advice 2013, Book 1
Table 2
Contributors of data for the analysis of seabird satellite tracking are as follows; full details about each
dataset are available via www.seabirdtracking.org
Species
Site
Owner
Corys Shearwater
Azores
J. González-Solís
Corys Shearwater
Balearics
J. González-Solís
Corys Shearwater
Canaries
J. González-Solís
Corys Shearwater
Chafarinas
J. González-Solís
Corys Shearwater
Berlengas
P. Catry, J.P. Granadeiro
Corys Shearwater
Selvagens
M.A. Dias, P. Catry
Corys Shearwater
Selvagens
M.A. Dias, J.P. Granadeiro
Corys Shearwater
Veneguera
J. González-Solís
Sooty Shearwater
Bay Fundy
R. Ronconi
Sooty Shearwater
Falklands
A. Hedd
Sooty Shearwater
Gough
A. Hedd
Great Shearwater
Bay Fundy
R. Ronconi
Great Shearwater
Inaccessible Island
R. Ronconi, P. Ryan, M. Caroline Martin
Manx Shearwater
Iceland
I.A. Sigurðsson, Y. Kolbeinsson, J. González-Solís
Manx Shearwater
UK
A. Ramsay, J. González-Solís
Fea’s Petrel
Bugio
I. Ramirez, V. Paiva
Black-legged Kittiwake
Norway
T. Boulinier, D. Gremillet, J. González-Solís
Little Shearwater
Azores
V. Neves, J. González-Solís
Zino’s Petrel
Madeira
F. Zino, R.A. Phillips, M. Biscoito
Figure 2
Species occurrence by month within the Hatton-Rockall area, showing percentage of tracked population
for each species (and where relevant subpopulation) found within the area each month.
Rights and permissions – Any requests to use the seabird tracking data shown for this site in any publication need to be
agreed with the data owners. An initial request should be sent to BirdLife International to coordinate this process. See
http://www.seabirdtracking.org/terms.php for full terms of reference
ICES Advice 2013, Book 1
289
ANNEX 2
Draft Proforma: Mid-Atlantic Ridge North of the Azores and South of Iceland
Presented by: Based on the Joint OSPAR/NEAFC/CBD Scientific Workshop. Reviewed and revised by an ICES expert
group.
Abstract
The Mid-Atlantic Ridge (MAR) is the major topographic feature of the Atlantic Ocean. Within the OSPAR/NEAFC area
the Northern MAR separates the Newfoundland and Labrador Basins from the West-European Basin and the Irminger
from the Iceland Basin. The ridge crest is generally cut by a deep rift valley along its length, bordered by high rift
mountains, which are bordered by high fractured plateaus. This region is largely composed of volcanic rock and is the
foundation of the proposed EBSA. Hydrothermal venting occurs along the ridges and small-scale physiographic features,
including many small volcanoes (seamounts) and canyons, form near the ridge axis. The Moytirra vent field, within this
EBSA, is the only high temperature hydrothermal vent known between the Azores and Iceland. Endemic vent fauna are
associated with thermally active areas. The 2,500 m depth contour is used to inform the EBSA boundary.
Introduction
Mid-ocean ridge systems occupy a third of the ocean floor and are the site of the formation of new Earth’s crust (Heezen
1969). The Mid-Atlantic Ridge (MAR), a tectonic continental plate boundary, is the major topographic feature of the
Atlantic Ocean, extending over 12,000 km from Iceland to the Bouvet Triple Junction in the South Atlantic (Figure 1). It
divides the ocean longitudinally into two halves, each cut by secondary transverse ridges and interrupted by strike-slip
transform faults that offset the ridge in opposing directions on either side of the axis of seafloor spreading (e.g., the Charlie
Gibbs Fracture at 53ºN). Compared with other mid-ocean ridges, the MAR is a slow-spreading ridge where new oceanic
floor is formed with an average spreading rate of 2.5 cm per year (Malinverno 1990). Hydrothermal venting occurs along
the ridges and small-scale physiographic features, including many small volcanoes (seamounts) and canyons, form near
the ridge axis; the crest consists mostly of hard volcanic rock. The MAR is an area which captures the Earth’s geological
history, with outstanding representation of the major stages of Earth’s history, including the record of life, significant ongoing geological processes in the development of landforms and significant geomorphic or physiographic features.
The general physiography of the MAR was documented some time ago (Heezen el al. 1959). The ridge crest is generally
notched by a deep rift valley along its length, bordered by high rift mountains, which in turn are bordered by high fractured
plateaus (Heezen et al. 1959). These crest zones are generally well defined and present along the full length of the MAR
(Malinverno 1990). At approximately 50 -75 km from the axis of the ridge, the crest merges with sediment covered flanks
which extend down to the abyssal plain (van Andel and Bowin 1968). The flanks are composed of a succession of smooth
shelves, each from 2 to 100 km from the central axis and subdivided into upper, middle, and lower steps (Heezen el al.
1959) extending in some areas to depths of 4,572 m (Tolstoy and Ewing 1949). The flanks are generally covered with
soft sediments. However, van Andel and Bowin (1968) describe considerable variability in sediment depth in the southern
MAR, where the foothill region west of the ridge and the ridge slope are only thinly covered, while sedimentation in some
valleys can range from nothing to a thickness of several hundred meters. The depth of the ridge crest is highly variable
along its length. Malinverno (1990) conducted 46 profiles across the ridge axis from 0° to 50°N, with most of those
conducted south of the Azores between 10° and 35°N. The average depth of the axial crest in those profiles was
approximately 2,300 m but Malinverno demonstrated that depth was correlated with distance from the Azores and fracture
zone characteristics.
The MAR is divided into the Northern and Southern ridges near the equator by the deep Romanche Trench. Within the
OSPAR area the Northern MAR separates the Newfoundland and Labrador Basins from the West-European Basin and
the Irminger from the Iceland Basin. It has a profound role in the circulation of the water masses in the North Atlantic
(Rossby 1999, Bower et al. 2002, Søiland et al. 2008) with currents crossing the MAR over deep gaps in the ridge and
influencing upper-ocean circulation patterns (Bower et al. 2002). Canyons cut into the flanks may influence upward fluxes
of water and abyssal mixing (Speer and Thurnherr 2005).
Studies of volcanic rocks from the submerged MAR suggest that it consists largely of tholeiitic basalt with low values of
K, Ti, and P. In contrast, the volcanic islands which form the elevated caps on the Ridge are built of alkali basalt with
high values of Ti, Fe3+, P, Na, and K (Engel and Engel 1964). Variations in mineral content result from chemical and
isotopic heterogeneity in the mantle (White and Schilling 1978).
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Moytirra Vent Field
The Moytirra vent field is the only fully described high temperature hydrothermal vent known between the Azores and
Iceland, making it a unique geophysical structure in the high seas of the North Atlantic and within the MAR. It is situated
at 45°N on the 300 m high fault scarp of the eastern axial wall of the MAR, 3.5 km from the axial volcanic ridge crest
(Wheeler et al. 2013). It is basalt-hosted and its position suggests that it is heated by an off-axis magma chamber. This
type of base rock causes precipitation of iron and sulphide-rich minerals during mixing of the hot hydothermal vent fluids
(200-400°C) with cold, oxygenated sea water- hence the term “black smoker” (Figure 2). The Moytirra vent field consists
of three active vent sites emitting “black smoke" and producing a complex of chimneys and beehive diffusers. The largest
chimney is 18 m tall and very actively venting.
There may also be further unconfirmed vent sites on the MAR at 43 N, at 45 N and on the Reykjanes Ridge. In these
areas, plumes and/or anomalously high concentrations of Mn in the water column have been detected
http://www.interridge.org/irvents/
Location
The Mid-Atlantic Ridge (MAR) extends over 12,000 km from Iceland to the Bouvet Triple Junction in the South Atlantic
(Figure 1) and falls within the national jurisdictions of Iceland and the Azores. The proposed EBSA Mid-Atlantic Ridge
North of the Azores and South of Iceland is for a portion of the MAR within the high-seas areas of OSPAR and NEAFC
(Figure 3). Although the crest has an average depth of approximately 2,300 m (Malinverno 1990) it is variable, and the
2,500 m depth contour was used to inform the boundaries of the proposed EBSA as this captures the majority of the ridge
crest, and known distribution of deep-water corals (maximum 2,400 m) (Figure 3, Table 1). Within the proposed EBSA
the smaller physiographic feature, the Moytirra Vent Field, is located at latitude 45.833 and longitude -27.85 (Table 1).
Feature description
The Mid-Atlantic Ridge North of the Azores and South of Iceland is a unique geomorphological feature to the North
Atlantic Ocean and to the high-seas areas of NEAFC and OSPAR. Within this feature is a smaller unique feature, the
Moytirra vent field. The Moytirra vent field is the only high temperature hydrothermal vent known between the Azores
and Iceland, making it a unique geophysical structure in the high seas of the North Atlantic and within the MAR.
The fauna of the Northern MAR have not been fully described and it is premature to speculate on whether any species
are endemic, excepting vent-endemic organisms associated with the hydrothermal vents. Some new species have been
described and these may prove to be endemic to the proposed EBSA with further sampling.
The benthic fauna associated with the Northern MAR are known from detailed observations at a few locations. Priede et
al. (2013) used a variety of sampling gears to survey habitat, biomass and biodiversity in a segment of the Northern MAR
as part of a multinational and multidisciplinary project (MAR-ECO). They found that primary production and export flux
over the MAR were not enhanced compared with a nearby reference station over the Porcupine Abyssal Plain and biomass
of benthic macrofauna and megafauna were similar to global averages at the same depths. Also as part of MAR-ECO,
Mortensen et al. (2008) used an ROV to conduct video surveys along the MAR at 8 sites between the Reykjanes Ridge
and the Azores. Deep-water corals were observed at all locations at depths less than 1400 m (range 800-2400 m) and 40
coral taxa were observed, including observations of patches of Lophelia pertusa. Crinoids, sponges, the bivalve Acesta
excavata, and squat lobsters were associated with the Lophelia. None of those corals were recognized as new species to
science and all likely have broader distributions extending along the continental slopes and seamounts at similar latitudes
in the North Atlantic. Inevitably, 11 new species have been described arising from the MAR-ECO work and more are
likely to be discovered as the samples are fully processed. These include a new genus and species of foram (Incola
arantius gen. et sp. nov.), two new species of glass sponges of the genus Sympagella (Rossellidae), mushroom corals
(Anthomastus gyratus sp. nov. and Heteropolypus sol sp. nov.), a deep-sea scavenging amphipod (Hirondellea
namarensis sp. nov.), two new starfish (species of Hymenaster) and three species of elasipodid holothurians (Gebruk et
al. 2013).
MAR-ECO midwater and bottom trawls collected 54 species of cephalopods in 29 families (Vecchione et al. 2010). The
squid Gonatus steenstrupi was the most abundant cephalopod in the samples, followed by the squids Mastigoteuthis
agassizii and Teuthowenia megalops. A multispecies aggregation of large cirrate octopods dominated the demersal
cephalopods.
The demersal fish fauna of the MAR form two distinct groups with a faunal divide between 48 and 52°N (Hareide and
Garnes 2001) and species-specific differences with depth (King et al. 2006, Bergstad et al. 2008). Hareide and Garnes
(2001), using one trawl and three longline surveys, identified 56 species from 27 families of fish from between 400 and
2000 m depth along the MAR. In the northern part of the Ridge (north of 52°N) relatively common sub-Arctic species
such as Sebastes spp., tusk (Brosme brosme) and Greenland halibut (Reinhardtius hippoglossoides) were dominant while
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sub-tropical species such as golden eye perch (Beryx splendens) and cardinal fish (Epigonus telescopus) were dominant
species below 48°N. During the 2004 MAR-ECO expedition to the MAR, 8518 fish, representing 40 species and 17
families were caught with longlines (Fossen et al. 2008). The 59 longline sets were distributed across the ridge axis at
depths ranging from 400 to 4300 m at two locations: just north of the Azores archipelago and in the Charlie–Gibbs
Fracture Zone. Chondrichthyans (primarily Etmopterus princeps) dominated the catches and contributed nearly 60% to
both total biomass and abundance. King et al. (2006) recorded the scavenging fishes of the MAR using a baited
autonomous lander equipped with a time-lapse camera between 924 and 3420 m water depth along 3 east–west transects
at 42, 51 and 53°N across the MAR. They photographed 22 taxa with Synaphobranchus kaupii, Antimora rostrata and
Coryphaenoides (Nematonurus) armatus dominant. Abyssal species in the axial valley region were C. armatus,
Histiobranchus bathybius and Spectrunculus sp. No endemic demersal species have been reported although the zoarcid
eelpout Pachycara thermophilum, is a vent-endemic species associated with hydrothermal vents of the MAR
(Geistdoerfer 1994).
Sutton et al. (2008) examined the assemblage structure and vertical distribution of deep-pelagic fishes relative to MAR
with acoustic and discrete-depth trawling surveys in association with MAR-ECO. A 36-station, zig-zag survey along the
Mid-Atlantic Ridge from Iceland to the Azores covered the full depth range (0 to >3000 m), from the surface to near the
bottom, using a combination of gear types to sample the pelagic fauna. Dominant families of pelagic fish included
Gonostomatidae, Melamphaidae, Microstomatidae, Myctophidae, and Sternoptychidae and 99 species of pelagic fish
were found concentrated particularly north of the Charlie-Gibbs Fracture Zone. Sutton et al. (2008) found that abundance
per volume of deep-pelagic fishes was highest in the epipelagic zone and within the benthic boundary layer (BBL; 0-200
m above the seafloor) while minimum fish abundance occurred at depths below 2300 m but above the BBL. Biomass per
volume of deep-pelagic fishes over the MAR reached a maximum within the BBL, revealing a topographic association
of a bathypelagic fish assemblage with the mid-ocean ridge system. The dominant component of deep-pelagic fish
biomass over the MAR was a wide-ranging bathypelagic assemblage that was remarkably consistent along the length of
the ridge from Iceland to the Azores. The authors conclude that special hydrodynamic and biotic features of mid-ocean
ridge systems cause changes in the ecological structure of deep-pelagic fish assemblages relative to those at the same
depths over abyssal plains.
Moytirra Vent Field
Due to the unique nature of the Moytirra vent field, the specialized vent fauna associated with it are also unique to the
North Atlantic high-seas area. Wheeler et al. (2013) have documented aggregations of gastropods (Peltospira sp.) and
populations of alvinocaridid shrimp (Mirocaris sp. and Rimicaris sp.) on the surfaces of the vent chimneys in addition to
bythograeid crabs (Segonzacia sp.) and zoarcid fish (Pachycara sp.), all considered hydrothermal vent fauna (van Dover
1995).
Feature condition, and future outlook
Given the geophysical nature, location and size of the MAR it is unlikely that it will be affected by human activities.
Despite its remoteness, the fauna associated with the MAR are not pristine. Starting in the early 1970s with Soviet/Russian
trawlers stocks of roundnose grenadier (Coryphaenoides rupestris), orange roughy (Hoplostethus atlanticus) and
alfonsino (Beryx splendens) associated with the MAR were exploited (Clark et al. 2007, ICES 2007). It can be assumed
that most hills along the ridge were at least explored (usually by midwater trawls operating close to the seafloor), and at
least 30 seamounts were also exploited for C. rupestris. After 1982, the targeted fishery for redfish developed, dwarfing
the catches of roundnose grenadier. After the transition from Soviet to Russian fisheries, the Russian fishing effort and
absolute catch on the MAR was significantly reduced, although catch per fishing day settled at relatively low levels by
the end of 1990s and the fishery was still conducted periodically (ICES 2007). The fishery on C. rupestris takes deepwater
redfish (Sebastes spp), orange roughy (H. atlanticus), blackscabbard fish (Aphanopus carbo) and deepwater sharks as
bycatch (Clark et al. 2007). Longline fishing and near-bottom pelagic trawls have the potential to damage fragile benthic
species such as deep-water corals and sponges. The scale of the impact that fishing and other human activities may have
had on the MAR fauna is at present unquantified. In 2009 NEAFC adopted measures that close more than 330,000 km2
to bottom fisheries on the MAR until 2015 (Figure 4).
According to the International Seabed Authority, exploratory mining for sulfide deposits has already been undertaken on
the MAR, while ferromanganese nodules and cobalt-rich ferromanganese crusts have potential for mining interests. The
potential impacts on the marine environment are removal of organisms and their habitats along with the mineral deposits
and the smothering of adjacent communities by any sediment plume that may be created
(http://www.isa.org.jm/en/about/faqs#16 ).
Representatives from Norway, Iceland, Azores,the United Kingdom, IUCN and UNESCO have met to review the
geological and biological heritage of the MAR in the North Atlantic (http://whc.unesco.org/en/activities/504/ ).
Discussions focused on the areas where the highest peaks of the mountain chain reach sea-level and form islands. Most
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of the underwater ridge was not considered because it lies outside any national territory and therefore is not covered by
provisions of the World Heritage Convention. There was agreement to encourage cooperation with other conventions in
order to better protect the biological, cultural and geological heritage of the ridge.
Assessment against CBD EBSA Criteria
CBD EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
Know
The area contains either (i) unique (“the only one of its
kind”), rare (occurs only in few locations) or endemic
species, populations or communities, and/or (ii) unique,
rare or distinct, habitats or ecosystems; and/or (iii) unique
or unusual geomorphological or oceanographic features
Explanation for ranking
Uniqueness or
rarity
High
X
The Mid-Atlantic Ridge (MAR) qualifies as a unique geomorphological feature in the North Atlantic. The Moytirra vent field is the
only known high temperature hydrothermal vent between the Azores and Iceland, making it a unique geophysical structure in the
high seas of the North Atlantic and within the MAR.
Areas that are required for a population to survive and
Special
importance for thrive
life-history
stages of species
Explanation for ranking
Data deficient
Importance for Area containing habitat for the survival and recovery of
endangered, threatened, declining species or area with
threatened,
endangered or significant assemblages of such species
declining species
and/or habitats
Explanation for ranking
X
X
Data deficient
Areas that contain a relatively high proportion of sensitive
Vulnerability,
habitats, biotopes or species that are functionally fragile
fragility,
sensitivity,
or (highly susceptible to degradation or depletion by human
activity or by natural events) or with slow recovery
slow recovery
Explanation for ranking
X
Deep-water corals were observed at all 8 sites from 3 locations along the proposed EBSA at depths less than 1400 m (range 8002400 m) and 40 coral taxa were observed, including observations of patches of Lophelia pertusa. These taxa are fragile with slow
recovery and highly susceptible to degradation or depletion by human activities including contact with bottom fishing gear
(longlines, pots, trawls).
Area containing species, populations or communities with
Biological
X
comparatively higher natural biological productivity
productivity
Explanation for ranking
The research conducted through the MAR-ECO project found that primary production and export flux over the MAR were not
enhanced compared with a nearby reference station over the Porcupine Abyssal Plain and biomass of benthic macrofauna and
megafauna were similar to global averages at the same depths. There is some evidence for pelagic fish concentrating in the benthic
boundary layer (to 200 m above the seafloor) over the MAR in association with topographic features.
Area contains comparatively higher diversity of
ecosystems, habitats, communities, or species, or has
higher genetic diversity
Explanation for ranking
Biological
diversity
X
Data deficient. Diversity of habitats is greater than that of surrounding abyssal plain but with the exception of the vent fauna,
habitats and species are generally shared with continental margins and seamounts not associated with the MAR.
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Sharing experiences and information applying other international criteria (Optional)
CBD EBSA Criterion
Description
Dependency:
An area where ecological processes are highly dependent
on biotically structured systems (e.g., coral reefs, kelp
forests, mangrove forests, seagrass beds). Such
ecosystems often have high diversity, which is dependent
on the structuring organisms. Dependency also embraces
the migratory routes of fish, reptiles, birds, mammals,
and invertebrates.
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
High
Know
Explanation for ranking
Representativeness:
An area that is an outstanding and illustrative example of
specific biodiversity, ecosystems, ecological or
physiographic processes
Explanation for ranking
Biogeographic
importance:
An area that either contains rare biogeographic qualities
or is representative of a biogeographic “type” or types, or
contains unique or unusual biological, chemical,
physical, or geological features
X
Explanation for ranking
The Mid-Atlantic Ridge (MAR) qualifies as a unique geomorphological feature in the North Atlantic. The Moytirra vent field is the
only known high temperature hydrothermal vent between the Azores and Iceland, making it a unique geophysical structure in the
high seas of the North Atlantic and within the MAR. Fauna endemic to the vents have adapted to the chemical and thermal properties
of the environment.
Structural complexity:
An area that is characterized by complex physical
structures created by significant concentrations of biotic
and abiotic features.
Explanation for ranking
Natural Beauty:
An area that contains superlative natural phenomena or
areas of exceptional natural beauty and aesthetic
importance.
Explanation for ranking
Earth’s geological
history:
An area with outstanding examples representing major
stages of Earth’s history, including the record of life,
significant on-going geological processes in the
development of landforms, or significant geomorphic or
physiographic features.
X
Explanation for ranking
The Mid-Atlantic Ridge is the site of significant on-going geological processes (plate tectonics, formation of new Earth’s crust) and
of significant physiographic features (axial rift valley, hydrothermal vent fields).
[Other relevant
criterion]
Explanation for ranking
[Other relevant
criterion]
Explanation for ranking
294
ICES Advice 2013, Book 1
References
Bergstad, O.A., Menezes,G. and Å.S. Høines. 2008. Demersal fish on a mid-ocean ridge: Distribution patterns and
structuring factors. Deep Sea Research Part II: Topical Studies in Oceanography 55(1–2): 185-202.
Bower, A.S., Le Cann, B., Rossby, T., Zenk, W., Gould, J., Speer, K., Richardson, P.L., Prater, M.D. and H.-M. Zhang.
2002. Directly measured mid-depth circulation in the northeastern North Atlantic Ocean. Nature 419: 603- 607.
Clark, M.R., Vinnichencko, V.I., Gordon, J.D.M., Beck-Bulat, G.Z., et al. 2007. Large-scale distant-water trawl fisheries
on seamounts. In: Pitcher, T.J., Morato, T., Hart, P.J.B., Clark, M.R., Haggan, N. and Santos, R.S. (eds)
Seamounts: Ecology, Conservation and Management. Fish and Aquatic Resources Series, Blackwell, Oxford,
UK. Chapter 17, pp. 361 – 399.
Engel, A.E.J. and C.G. Engel. 1964. Composition of basalts from the Mid-Atlantic Ridge. Science 144 (3624): 13301333.
Fossen, I., Cotton, C.F., Bergstad, O.A. and J.E. Dyb. 2008. Species composition and distribution patterns of fishes
captured by longlines on the Mid-Atlantic Ridge. Deep Sea Research Part II: Topical Studies in Oceanography
55(1–2): 203-217.
Gebruk , A.V., Priede, I.G., Fenchel T. and F. Uiblein. 2013. Benthos of the sub-polar front area on the Mid-Atlantic
Ridge: Results of the ECOMAR project. Marine Biology Research 9(5-6): 443-446.
Geistdoerfer, P. 1994. Pachycara thermophilum, une nouvelle espèce de poisson Zoarcidae des sites hydrothermaux de
la dorsale médio-atlantique. Cybium 18: 109-115.
Hareide, N.-R. and G. Garnes. 2001. The distribution and catch rates of deep water fish along the Mid-Atlantic Ridge
from 43 to 61°N. Fisheries Research 51(2–3): 297-310.
Heezen, B.C.,Tharp, M. and M. Ewing. 1959. The Floors of the Oceans: I. The North Atlantic. The Geological Society
of America Special Paper 65, 122 pp.
Heezen, BC. 1969. The world rift system: An introduction to the symposium. Tectonophysics 8:269-279.
ICES. 2007. Report of the Working Group on Deep-water Ecology (WGDEC), 26 – 28th February. ICES CM
2007/ACE:01 Ref. LRC. 61pp.
King, N.J., P.M. Bagley and I.G. Priede. 2006. Depth zonation and latitudinal distribution of deep-sea scavenging
demersal fishes of the Mid-Atlantic Ridge, 42 to 53ºN. Marine Ecology Progress Series 319: 263-274.
Malinverno, A. 1990. A quantitative study of axial topography of the Mid-Atlantic Ridge. Journal of Geophysical
Research 95: 2645-2660.
Mortensen, P.B., Buhl-Mortensen, L., Gebruk, A.V. and E. M. Krylova. 2008. Occurrence of deep-water corals on the
Mid-Atlantic Ridge based on MAR-ECO data. Deep-Sea Research II 55:142-152.
Priede, I.G., Bergstad, O.A., Miller, P.I., Vecchione, M., Gebruk, A., et al. 2013. Does Presence of a Mid-Ocean Ridge
Enhance Biomass and Biodiversity? PLoSONE 8(5): e61550. doi:10.1371/journal.pone.0061550
Rossby, T. 1999. On gyre interactions. Deep-Sea Research II 46: 139-164.
Søiland, H., Budgell, W.P. and Ø Knutsen. 2008. The physical oceanographic conditions along the Mid-Atlantic Ridge
north of the Azores in June-July 2004. Deep-Sea Research II 55: 29- 44.
Speer, K. G. and A. M. Thurnherr. 2005. Abyssal Canyons and Mixing by Low-Frequency Flow. In: P. Muller and D.
Henderson (Editors), Near-Boundary Processes and Their Parameterization, topics in physical oceanography,
'Aha Huliko' a Winter Workshop, pp. 17-19.
Sutton, T.T., Porteiro, F.M., Heino, M., et al. 2008. Vertical structure, biomass and topographic association of deeppelagic fishes in relation to a mid-ocean ridge system. Deep-Sea Research II 55 (1–2):161–184.
Tolstoy, I. and M. Ewing. 1949. North Atlantic hydrography and the Mid-Atlantic Ridge. Bulletin of the Geological
Society of America 60(10): 1527-1540.
van Andel, Tj. H. and C. O. Bowin. 1968. Mid-Atlantic Ridge between 22º and 23º north latitude and the tectonics of
mid-ocean rises. Journal of Geophysical Research 73: 1279-1298.
Van Dover, C.L. 1995. Ecology of Mid-Atlantic Ridge hydrothermal vents. Geological Society, London, Special
Publications 1995, v. 87, p257-294.
Vecchione, M., Young, R.E. and U. Piatkowski. 2010. Cephalopods of the northern Mid-Atlantic Ridge. Marine Biology
Research 6: 25–52.
Wheeler, A.J., Murton, B., Copley, J., Lim, A., Carlsson, J. et al. 2013. Moytirra: discovery of the first known deep-sea
hydrothermal vent field on the slow-spreading Mid-Atlantic Ridge north of the Azores. Geochemistry,
Geophysics, Geosystems, doi: 10.1002/ggge.20243.
White, W.M. and J.-G. Schilling. 1978. The nature and origin of geochemical variation in Mid-Atlantic Ridge basalts
from the Central North Atlantic. Geochimica et Cosmochimica Acta 42 (10): 1501-1516.
ICES Advice 2013, Book 1
295
Tables, Maps and Figures
Table 1
Boundaries for the proposed EBSA Mid-Atlantic Ridge North of the Azores and South of Iceland and
location of the Moytirra Vent Field (see Figure 3).
Feature
Point 1
Point 2
Point 3
Point 4
Point 5
Point 6
EEZ of the Azores
Latitude
63.59
55.85
52.97
52.50
47.11
43.18
Point 7
Point 8
Point 9
Point 10
Point 11
Point 12
EEZ of Iceland
42.50
46.43
49.43
52.50
53.78
60.13
Moytirra Vent Field
296
(dd)
Longitude (dd)
-30.91
-37.51
-36.70
-33.00
-28.09
-30.59
Details of Location
Reference
easterly following
the EEZ boundary
for the Azores to
Point 7
45.4833
-27.55
-25.91
-26.63
-29.80
-33.69
-22.84
-27.85
westerly following
the EEZ boundary
for Iceland to join
Point 1
300 m high fault
scarp of the eastern
axial wall, 3.5 km
from
the
axial
volcanic ridge crest
Wheeler et al. (2013)
ICES Advice 2013, Book 1
Figure 1
Location of the Mid-Atlantic Ridge (dashed lines). Image downloaded from: commons.wikimedia.org
File:Mid-atlantic ridge.jpg - Wikimedia Commons.
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297
Figure 2
298
Volcanically heated fluid rises from a deep-sea "black-smoker" in the Moytirra vent field. (Photo
http://news.nationalgeographic.com/news/2011/08/110808-hydrothermal-ventsdownloaded
from
volcanic-animals-ocean-deep-sea-science-alien/ )
ICES Advice 2013, Book 1
Figure 3
Location of the proposed EBSA Mid-Atlantic Ridge North of the Azores and South of Iceland. The perimeter
of the proposed boundary follows Table 1 with points numbered 1 through 12. The blue shaded areas
represent the Exclusive Economic Zones of countries in the region. The light green line outlines the outer
boundary of the OSPAR Convention Area which coincides with the NEAFC Convention Area at its western
and southern boundary. Seafloor bathymetry is indicated in grayscale with the 2000 m (red) and 2500 m
(light blue) General Bathymetric Chart of the Oceans (GEBCO) depth contours indicated. The red circle
with the central star marks the location of the Moytirra Vent Field. See Table 1 for positional information
(latitude and longitude).
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Figure 4
300
Location of areas closed to bottom fishing (2009-2015) in the NEAFC regulatory area which includes the
MAR http://www.neafc.org/page/closures. There is a small seasonal closure for Blue Ling near the
boundary with Iceland EEZ which is not visible at this scale.
ICES Advice 2013, Book 1
ANNEX 3
Draft Proforma: Charlie-Gibbs Fracture Zone
Presented by: Based on the Joint OSPAR/NEAFC/CBD Scientific Workshop. Reviewed by revised by an ICES expert
group
Abstract
Fracture zones are common topographic features of the global oceans that arise through plate tectonics. The CharlieGibbs Fracture Zone is an unusual left lateral strike-slip double transform fault in the North Atlantic Ocean along which
the rift valley of the Mid-Atlantic Ridge is offset by 350 km near 52º30′N. It opens the deepest connection between the
northwest and northeast Atlantic (maximum depth of approximately 4500 m) and is approximately 2000 km in length
extending from about 25°W to 45°W. It is the most prominent interruption of the MAR between the Azores and Iceland
and the only fracture zone between Europe and North America that has an offset of this size. Two named seamounts are
associated with the transform faults: Minia and Hecate. The CGFZ is considered a unique geomorphological feature in
the North Atlantic under the EBSA criteria; further, it captures the Earth’s geological history, including significant ongoing geological processes.
Introduction
Fracture zones are common topographic features of the global oceans that arise through plate tectonics. They are
characterized by two strongly contrasting types of topography. Seismically active transform faults form near mid-ocean
ridges where the continental plates move in opposing directions at their junction. Seismically inactive fracture zones,
where the plate segments move in the same direction, extend beyond the transform faults often for 100s of kilometers.
Their atypical crust thickness that can be as little as 2 km (Mutter et al. 1984, Cormier et al. 1984, Calvert and Whitmarsh
1986) allowing direct seismic investigations of the internal structure and composition of oceanic crusts used to model
processes of seafloor spreading. In the Atlantic Ocean most fracture zones originate from the Mid-Atlantic Ridge (MAR)
and are nearly perfectly west - east oriented. There are about 300 fracture zones occurring on average every 55 km along
the ridge, with the offsets created by transform faults ranging from 9 to 400 km in length (Müller and Roest 1992).
The Charlie-Gibbs Fracture Zone (CGFZ) is an unusual left lateral strike-slip double transform fault in the North Atlantic
Ocean along which the rift valley of the MAR is offset by 350 km near 52º30′N (Figure 1). It opens the deepest connection
between the northwest and northeast Atlantic (maximum depth of approximately 4500 m; Fleming et al. 1970) and is
approximately 2000 km in length extending from about 25°W to 45°W. It is the most prominent interruption of the MAR
between the Azores and Iceland and the only fracture zone between Europe and North America that has an offset of this
size 22. Knowledge of its geomorphology is considered essential to the understanding of the plate tectonic history of the
Atlantic north of the Azores (Olivet et al. 1974). For these reasons it is consider a unique geomorphological feature in the
North Atlantic under the EBSA criteria; further, it captures the Earth’s geological history, including significant on-going
geological processes.
The CGFZ is comprised of two narrow parallel fracture zones (Fleming et al. 1970) which form deep trenches located at
30ºW (Charlie-Gibbs South Transform Fault) and at 35º15′W (Charlie-Gibbs North Transform Fault) and separated by a
short (40 km) north-south seismically active (Bergman and Solomon 1988) spreading center (median transverse ridge) at
31º45’W (Figure 2; Searle 1981; Fleming et al. 1970, Olivet et al. 1974). The southern fault displaces the MAR, coming
from the Azores, to the west over a distance of 120 km. It is at most 30 km wide (Searle 1981). The northern fault displaces
the spreading ridge over another 230 km to the west before it connects to the northern part of the MAR going to Iceland.
Both transform faults continue eastward and westward as inactive fracture zones (Figure 2).
The CGFZ is characterized by rough morphology and the walls of the fracture valleys and the ridge in between them are
broken and irregular with slopes of up to 29° (Fleming et al. 1970). The height of the ridge between the faults is at least
1000 m below the surface and as shallow as 636 m in parts (Fleming et al. 1970). Rock samples show the walls of the
fracture zone to be both basaltic and ultramafic while the median transverse ridge contains gabbro (Hekinian and Aumento
1973). Earthquake epicentres are associated with the transform faults (Kanamori and Stewart 1976, Bergman and
Solomon 1988) and an almost continuous belt of epicentres follow the southern end of the Reykjanes Ridge, along the
northern transform valley, the central median valley and the southern transform valley to the north end of the MAR
(Lilwall and Kirk 1985). Two named seamounts are associated with the transform faults: Minia Seamount (53°01′N
34°58′W) located near the junction of the Reykjanes Ridge and the northern transform fault and Hecate Seamount
22
The Spitzbergen and Jan Mayen fracture zones, of comparable offset (145 and 211 km respectively), lie between Greenland and Europe.
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(52°17′N 31°00′W) located on the northern wall of the southern transform fault east of the short median transverse ridge
(Figure 2; Fleming et al. 1970).
Ridge and troughs along the CGFZ are mostly covered with muddy sediments (Fleming et al. 1970) although outcrops of
sedimentary rock and boulder fields are exposed by recent faulting and current scour (Shor et al. 1980, Searle 1981) and
the southern transform near 30°30′W has no sediment cover (Searle 1981). Considerable thicknesses of sediment are
deposited in the northern transform valley from the Iceland-Scotland Overflow Water (ISOW) which carries a significant
load of suspended sediment (25 μg I-1) as it passes through (Shor et al. 1980). Transverse ridges prevent the sediment
reaching the southern valley (Searle 1981) which has less sediment cover, although it is still considered a depositional
environment (Shor et al. 1980).
The topography of the CGFZ has a major influence on deep water oceanographic circulation (Harvey and Theodorou
1986). A large component of the North Atlantic Deep Water originates in the Norwegian Sea and flows south over the
sills between Scotland and Iceland (ISOW). It meets the CGFZ near the intersection of the transform faults and the
spreading centre (Shor et al. 1980). There is then a westward movement of deep water passing through the fracture zone
from east to west through to the Irminger Sea occurring from the core depth of the ISOW at about 2500 m to the sea floor
(Garner 1972, Shor et al. 1980, Saunders 1994). Most of this water is carried through the northern transform fault where
the overflow water first encounters the fracture zone.
The topography of the CGFZ also is thought to have some influence on the circulation of surface waters, although they
are not locked to the bottom features to the same extent as the ISOW (Rossby 1999, Bower et al. 2002). The northern
branch of the North Atlantic Current defines the location of the sub-polar front between colder Sub Arctic Intermediate
Water to the north and warmer North Atlantic Intermediate Water to the south (Søiland et al. 2008). The sub-polar front
meanders between 48-53°N and surface flow is predominantly eastward. The CGFZ is therefore not only a topographic
discontinuity in the MAR but the area also constitutes an oceanographic transition zone between waters of different
temperatures and flow regimes (Priede et al. 2013).
Location
The Charlie-Gibbs Fracture Zone occurs at 52º30′N and extends from about 25°W to 45°W with the transform faults
occurring between 30°W and 35°W (Olivet et al. 1974). The proposed Charlie-Gibbs Fracture Zone EBSA within the
high-seas area of NEAFC and OSPAR takes the co-ordinates provided in Table 1 and illustrated in Figure 3. These are
based on Olivet et al. (1974) and the location of the Minia Seamount which influences the northern boundary of the
EBSA. The eastern boundary of the CGFZ is detectable beyond 42°W, the outer boundary of the NEFAC/OSPAR
jurisdictions. The southern ridge continues uninterrupted to 45°W (Olivet et al. 1974).
Feature description
The Charlie-Gibbs Fracture Zone (CGFZ) is a unique geomorphological feature to the North Atlantic Ocean and to the
high-seas areas of NEAFC and OSPAR. Owing to its remoteness, the fauna associated with the CGFZ are poorly studied
and it is premature to speculate on whether any species are endemic based on first descriptions. For example, Gebruk
(2008) described two species of holothurians and believed them to be endemic to the Mid-Atlantic Ridge but they
subsequently were found on the European continental margin in the Whittard Canyon (Masson 2009).
As part of the MAR-ECO project (Priede et al. 2013) manned submersibles were deployed on the axis (52°47′N) and the
northern slopes (52°58′N) of the Charlie–Gibbs North transform fault and surveyed macroplankton (Vinogradov 2005),
demersal nekton (Felley et al. 2008) and invertebrate megafauna (Gebruk and Krylova 2013). Pelagic shrimps,
chaetognaths and gelatinous animals were numerically dominant in the plankton, with peak densities corresponding to
the main pycnocline. Mucous houses of appendicularians were abundant at 150 m above the seabed, although this is
common throughout the central Atlantic and not associated with specific bottom topography (Vinogradov 2005). Nekton
included large and small macrourids (Coryphaenoides spp.), shrimp (infraorder Penaeidea), Halosauropsis macrochir,
Aldrovandia sp., Antimora rostrata, and alepocephalids (Felley et al. 2008).
Glass sponges were common between 1700 and 2500 m while the deeper parts of the fracture wall and the sea floor were
dominated by isidid corals, other anthozoans, squat lobsters and echinoderms, especially holothurians. The elpidiid
holothurian, Kolga nana, occurred at high density in the abyssal depression (Gebruk and Krylova 2013). Rogacheva et
al. (2013) recorded 32 holothurian species from the CGFZ area through the ECOMAR project
(http://www.oceanlab.abdn.ac.uk/ecomar/), including three elasipodid holothurian species new to science.
In general, none of the fauna documented from the CGFZ showed distributions atypical of similar habitats in the broader
North Atlantic, although Gebruk and Krylova (2013) discuss the known distribution of the holothurian Peniagone
longipaillata and remark on the differences in relative abundance observed between the occurrence of this species, where
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it is common in the lower bathyl of the CGFZ, and the continental slopes in the Porcupine Seabight and Abyssal Plain
areas and Whitard Canyon where it appears less so. There is weak evidence that the CGFZ may be important for juvenile
zoarcids based on a high percentage of those observed with baited cameras being <100 mm in length (Kemp et al. 2013).
General knowledge of seafloor benthos suggests that where the geo-morphological processes of the fracture zone have
created steep walls along the fractures, the greater three-dimensional topographic complexity, combined with the strong
water flows through the fractures, creates habitat that is likely to be more productive and support greater concentrations
of fragile taxa such as deep-water corals and sponges than adjacent habitats (Miller et al. 2012). The sampling done
along the fracture zone supports these inferences but the differences from other habitats in similar depths and latitudes
have not been quantified yet.
Feature condition, and future outlook
Given the geophysical nature, location and size of the Charlie-Gibbs Fracture Zone (CGFZ) it is unlikely that it will be
affected by human activities, although there is potential for mining of the rare minerals associated with the transform
faults. In 2010 the Environmental Ministers of the OSPAR countries officially designated a marine protected area of
145,420 km2 in the southern part of the Charlie-Gibbs Fracture Zone (Figure 4) and adopted “significant and innovative
measures to establish and manage the southern part of the originally proposed Charlie-Gibbs Fracture Zone MPA –
“Charlie-Gibbs South MPA”-, for which the seabed and super adjacent waters are situated in areas beyond national
jurisdiction” (OSPAR Commission 2010). That same year (2010) the OSPAR Commission and the International Seabed
Authority signed a memorandum of understanding in order to conciliate the development of mineral resources with
comprehensive protection of the marine environment. In this MOU, the Charlie Gibbs Fracture Zone is highlighted as an
area where consultation between the two parties had been initiated. In 2012 OSPAR countries designated “ Charlie-Gibbs
North High Seas Marine Protected Area”, an area of high seas of approximately 177,700 km2 (OSPAR Commission
2012), complementing the Charlie-Gibbs South MPA established previously (Figure 4).
The scale of the impact that fishing and other human activities have had on the fauna of the CGFZ is at present
unquantified and likely to be minor, although fishing has been reported on the Hectate Seamount (ICES 2007). In 2009
NEAFC closed more than 330,000 km2 to bottom fisheries on the Mid-Atlantic Ridge, including a large section of the
CGFZ which includes the transform faults and median transverse ridge (http://www.neafc.org/page/closures) (Figure 4).
Assessment against CBD EBSA Criteria
[Discuss the case study in relation to each of the CBD criteria and relate the best available science. Note that a candidate
EBSA may qualify on the basis of one or more of the criteria, the boundaries of the EBSA need not be defined with exact
precision. And modeling may be used to estimate the presence of EBSA attributes. Please note where there are significant
information gaps.]
CBD
EBSA
Criterion
Description
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
Know
The area contains either (i) unique (“the only one of its
kind”), rare (occurs only in few locations) or endemic
species, populations or communities, and/or (ii) unique,
rare or distinct, habitats or ecosystems; and/or (iii) unique
or unusual geomorphological or oceanographic features
Explanation for ranking
Uniqueness
rarity
or
High
X
The Charlie-Gibbs Fracture Zone (CGFZ) is a unique geomorpholical feature in the high-sea between the Azores and Iceland. It is
the only fracture zone with an offset of its size (350 km) between Europe and North America and opens the deepest connection
between the northwest and northeast Atlantic. The fact that it is a double transform fault is an unusual feature.
Areas that are required for a population to survive and
Special
importance for thrive
life-history
stages of species
Explanation for ranking
X
Data deficient
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303
Importance for Area containing habitat for the survival and recovery of
endangered, threatened, declining species or area with
threatened,
endangered or significant assemblages of such species
declining species
and/or habitats
Explanation for ranking
X
Data deficient
Areas that contain a relatively high proportion of sensitive
Vulnerability,
habitats, biotopes or species that are functionally fragile
fragility,
sensitivity,
or (highly susceptible to degradation or depletion by human
activity or by natural events) or with slow recovery
slow recovery
Explanation for ranking
X
Glass sponges were observed on hard substrates on the fault wall at depths between 1700 and 2500 m. These taxa are fragile with
slow recovery and highly susceptible to degradation or depletion by human activities including contact with bottom fishing gear
(longlines, pots, trawls).Inferring from the frequently documented presence of such species and communities in structurally complex
deep-sea habitats elsewhere, further sampling is likely to document additional presence of sensitive habitats, biotopes, or species in
the CGFZ fractures,
Area containing species, populations or communities with X
Biological
comparatively higher natural biological productivity
productivity
Explanation for ranking
There is no evidence that the CGFZ contains comparatively higher natural productivity. The strong current flows through the
fractures and complex three dimensional habitats create conditions that may enhance productivity, but at present there are
insufficient data to rank on this criterion.
Area contains comparatively higher diversity of
Biological
X
ecosystems, habitats, communities, or species, or has
diversity
higher genetic diversity
Explanation for ranking
Diversity of habitats is greater than that of surrounding abyssal plain but biotic diversity is poorly quantified and there is little basis
for a comparative assessment on this criterion at this time.
Sharing experiences and information applying other international criteria (Optional)
CBD EBSA Criterion
Description
Dependency:
An area where ecological processes are highly dependent
on biotically structured systems (e.g., coral reefs, kelp
forests, mangrove forests, seagrass beds). Such
ecosystems often have high diversity, which is dependent
on the structuring organisms. Dependency also embraces
the migratory routes of fish, reptiles, birds, mammals,
and invertebrates.
Ranking of criterion relevance
(please mark one column with an X)
Don’t
Low
Some
High
Know
Explanation for ranking
Representativeness:
An area that is an outstanding and illustrative example of
specific biodiversity, ecosystems, ecological or
physiographic processes
Explanation for ranking
Biogeographic
importance:
An area that either contains rare biogeographic qualities
or is representative of a biogeographic “type” or types, or
contains unique or unusual biological, chemical,
physical, or geological features
X
Explanation for ranking
The CGFZ qualifies as a unique geomorphological feature in the North Atlantic being the largest transform fault separating Europe
from North America.
An area that is characterized by complex physical
Structural complexity:
structures created by significant concentrations of biotic
and abiotic features.
Explanation for ranking
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Natural Beauty:
An area that contains superlative natural phenomena or
areas of exceptional natural beauty and aesthetic
importance.
Explanation for ranking
Earth’s geological
history:
An area with outstanding examples representing major
stages of Earth’s history, including the record of life,
significant on-going geological processes in the
development of landforms, or significant geomorphic or
physiographic features.
X
Explanation for ranking
Fracture zones are of great geological interest due to their anomalous crust thickness that can be as little as 2 km allowing direct
seismic investigations of the internal structure and composition of oceanic crusts used to model processes of seafloor spreading.
Knowledge of the geomorphology of the CGFZ is considered essential to the understanding of the plate tectonic history of the
Atlantic north of the Azores.
[Other relevant
criterion]
Explanation for ranking
[Other relevant
criterion]
Explanation for ranking
References
Bergman, E.A. and S.C. Solomon. 1988. Transform fault earthquakes in the North Atlantic: Source mechanisms and
depth of faulting. Journal of Geophysical Research 93:9027-9057.
Bower, A.S., Le Cann, B., Rossby, T., Zenk, W., Gould, J., Speer, K., Richardson, P.L., Prater, M.D. and H.-M. Zhang.
2002. Directly measured mid-depth circulation in the northeastern North Atlantic Ocean. Nature 419: 603- 607
Calvert, A.J. and R.B. Whitmarsh. 1986. The structure of the Charlie-Gibbs Fracture Zone. Journal of the Geological
Society 1433: 819-821.
Cormier, M.-H., Detrick, R. S. and G. M. Purdy. 1984. Anomalously thin crust in oceanic fracture zones: New seismic
constraints from the Kane Fracture Zone. Journal of Geophysical Research 89:249–266.
Felley, J.D., Vecchione, M. And R.R. Wilson Jr. 2008. Small-scale distribution of deep-sea demersal nekton and other
megafauna in the Charlie-Gibbs Fracture Zone of the Mid-Atlantic Ridge. Deep Sea Research II 55: 153-160.
Fleming, H.S., Cherkis, N.Z. and J.R. Heirtzler. 1970. The Gibbs Fracture Zone: A double fracture zone at 52°30′N in
the Atlantic Ocean. Marine Geophysical Researches 1:37-45.
Garner, D.M. 1972. Flow through the Charlie-Gibbs Fracture Zone, Mid-Atlantic Ridge. Canadian Journal of Earth
Sciences 9: 116-121.
Gebruk A.V. 2008. Holothurians (Holothuroidea, Echinodermata) of the northern Mid-Atlantic Ridge collected by the
G.O. Sars MAR-ECO expedition with descriptions of four new species. Marine Biology Research 4, 48–60.
Gebruk, A.V. and E.M. Krylova. 2013. Megafauna of the Charlie–Gibbs Fracture Zone (northern Mid-Atlantic Ridge)
based on video observations. Journal of the Marine Biological Association of the United Kingdom 93: 1143-1150.
doi:10.1017/S0025315412001890.
Harvey, J.G. and A. Theodorou. 1986. The circulation of Norwegian Sea overflow water in the eastern North Atlantic.
Oceanologica Acta 9: 393-402.
Hekinian, R. and F. Aumento. 1973. Rocks from the Gibbs Fracture Zone and the Minia Seamount near 53°N in the
Atlantic Ocean. Marine Geology 14: 47-72.
ICES. 2007. Report of the Working Group on Deep-water Ecology (WGDEC), 26 – 28th February. ICES CM
2007/ACE:01 Ref. LRC. 61pp.
Kanamori, H. and G.S. Stewart. 1976. Mode of the strain release along the Gibbs Fracture Zone, Mid-Atlantic Ridge.
Physcis of the Earth and Planetary Interiors 11: 312-332.
Kemp, K.M., Jamieson, A.J., Bagley, P.M., Collins, M.A. and I.G. Priede. 2008. A new technique for periodic bait release
at a deep-sea camera platform: First results from the Charlie-Gibbs Fracture Zone, Mid-Atlantic Ridge. Deep-Sea
Research II 55: 218-228.
Lilwall, R.C. and R.E. Kirk. 1985. Ocean-bottom seismograph observations on the Charlie-Gibbs fracture zone.
Geophysical Journal of the Royal Astronomical Society 80: 195-208.
Masson, D.G. 2009. The Geobiology of Whittard Submarine Canyon. RRS James Cook Cruise 36, 19 June–28 July 2009.
National Oceanography Centre, Southampton, 53 pp. http://www.eprints.soton.ac.uk/69504/1/nocscr041.pdf.
Miller, R.J., Hocevar, J., Stone, R.P. and D.V. Fedorov. 2012. Structure-forming corals and sponges and their use as fish
habitat in Bering Sea submarine canyons. PLoS ONE 7(3): e33885. doi:10.1371/journal.pone.0033885
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Müller, R.D. and W.R. Roest. 1992. Fracture zones in the North Atlantic from combined Geosat and Seasta data. Journal
of Geophysical Research 97: 3337-3350.
Mutter, J.C., Detrick, R.S. and North Atlantic Transect Study Group. 1984. Multichannel seismic evidence for
anomalously thin crust at Blake Spur fracture zone. Geology 12: 534-537.
Olivet, J.-L., Le Pichon, Xl, Monti, S. and B. Sichler. 1974. Charlie-Gibbs Fracture Zone. Journal of Geophysical
Research 79: 2059-2072.
OSPAR Commission. 2010. OSPAR Convention for the Protection of the Marine Environment of the North-East Atlantic.
Meeting of the OSPAR Commission Bergen: 20-24 September 2010. Annex 49 (Ref. M6.2).
http://www.ospar.org/content/content.asp?menu=01441000000000_000000_000000
OSPAR Commission. 2012. OSPAR Convention for the Protection of the Marine Environment of the North-East Atlantic.
Meeting of the OSPAR Commission Bonn: 25-29 June 2012. Annex 6 (Ref. §5.19a). OSPAR Decision 2012/01.
Priede, I.G., Billett, D.S.M., Brierley, A.S., Hoelzel, A.R., Inall, M., Miller, P.I., Cousins, N.J., Shields, M.A. and T.
Fujii. 2013. The ecosystem of the Mid-Atlantic Ridge at the sub-polar front and Charlie-Gibbs Fracture Zone;
ECO-MAR project strategy and description of the sampling programme 2007-2010. Deep-Sea Research II
http://dx.doi.org/10.1016/j.dsr2.2013.06.012i.
Rogacheva A, Gebruk A. and C.Alt. 2013. Deep-sea holothurians of the Charlie Gibbs Fracture Zone area, northern MidAtlantic Ridge. Marine Biology Research 9:587_623.
Rossby, T. 1999. On gyre interactions. Deep-Sea Research II 46: 139-164.
Saunders, P.M. 1994.The flux of overflow water through the Charlie–Gibbs Fracture Zone. Journal of Geophysical
Research 99:12343–12355.
Searle, R. 1981. The active part of the Charlie-Gibbs Fracture Zone: A study using sonar and other geophysical
techniques. Journal of Geophysical Research 86: 243-262.
Shor, A., Lonsdale, P., Hollister, C.D. and D. Spencer. 1980. Charlie-Gibbs fracture zone: bottom-water transport and its
geological effects. Deep-Sea Research 27A: 325-245.
Søiland, H., Budgell, W.P. and Ø Knutsen. 2008. The physical oceanographic conditions along the Mid-Atlantic Ridge
north of the Azores in June-July 2004. Deep-Sea Research II 55: 29- 44.
Vinogradov, G.M. 2005. Vertical distribution of macroplankton at the Charlie-Gibbs Fracture Zone (North Atlantic), as
observed from the manned submersible “Mir-1”. Marine Biology 146: 325-331.
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Tables, Maps and Figures
Table 1.
Boundaries for the proposed EBSA Charlie-Gibbs Fracture Zone and location of the Minia and Hecate
Seamounts (see Figure 3).
Feature
CGFZ Proposed EBSA
Point 1
CGFZ Proposed EBSA
Point 2
CGFZ Proposed EBSA
Point 3
CGFZ Proposed EBSA
Point 4
CGFZ Proposed EBSA
Point 5
Northern
Fracture
(eastern portion)
Southern Fracture
(eastern portion)
Northern
Fracture
(western portion)
Southern Fracture
(western portion)
Minia Seamount
Hecate Seamount
ICES Advice 2013, Book 1
Latitude
(dd)
Longitude
(dd)
51°N
42°W
53°05′N
42°W
53°05′N
30°W
52°30′N
25°W
51°45′N
25°W
53°05′N
42°W
51°N
45°W
52°30′N
27°W
51°45′N
25°W
53°01′N
34°58′W
53º 00.60' N
34º 49.80' W
52°17′N
31°00′W
52º 15.60' N
31º 03.00' W
Details
Location
of
Reference
Olivet
8)
Olivet
8)
Olivet
11)
Olivet
11)
located near the
junction of the
Reykjanes Ridge
and the northern
transform fault
et al. 1974 (p. 2062, fig.
et al. 1974 (p. 2062, fig.
et al. 1974 (p. 2063, fig.
et al. 1974 (p. 2064, fig.
Fleming et al. 1970
Seamount Catalogue
http://earthref.org/SC/SMNT530N-0348W/
located on the
northern wall of
the
southern
transform fault east
of the short median
transverse ridge
Fleming et al. 1970
Seamount Catalogue
http://earthref.org/SC/SMNT530N-0348W/
307
Figure 1
308
Location of the Charlie-Gibbs Fracture Zone (black lines) in the North Atlantic. The Mid-Atlantic Ridge
runs through the centre of the Atlantic Ocean and its left lateral displacement can be clearly seen. Image
downloaded from: commons.wikimedia.org File:Charlie-gibbs-full-extent.png - Wikimedia Commons.
ICES Advice 2013, Book 1
Figure 2
Schematic of the Charlie-Gibbs Fracture Zone and the Mid-Atlantic Ridge (MAR) indicating the
left lateral displacement of the MAR, the North and South transform faults and the central spreading
axis. The relative location of two seamounts, Hecate and Minia are illustrated. Image downloaded
from: commons.wikimedia.org File:Charliegibbsschema-en.svg- Wikimedia Commons.
Figure 3.
Proposed Charlie-Gibbs Fracture Zone EBSA (yellow lines). Numbers refer to the points in Table 1. The
green line is the NEAFC/OSPAR outer boundary.
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309
Figure 4.
310
Location of the OSPAR MPAs in the North Atlantic including the large Charlie-Gibbs South and CharlieGibbs North MPAs in the central area. The areas closed to bottom fishing by NEAFC are indicated by the
yellow boundaries. Downloaded 10 Sep 2013 from: http://charlie-gibbs.org/charlie/node/70
ICES Advice 2013, Book 1
ANNEX 4
Draft Proforma - The Arctic Ice habitat - multiyear ice, seasonal ice and- marginal ice zone
Presented by WWF and reviewed by Participants at the Joint OSPAR/NEAFC/CBD Scientific Workshop on the
Identification of Ecologically or Biologically Significant Marine Areas in the North-East Atlantic. Reviewed and revised
by an ICES expert group.
Abstract
The permanently ice covered waters of the high Arctic provide a range of globally unique habitats associated with the
variety of ice conditions. In the northern hemisphere multi-year sea ice only exists in the Arctic and although the
projections of changing ice conditions due to climate change project a considerable loss of sea ice, in particular multiyear
ice, the Eurasian Central Arctic high seas are likely to at least keep the ice longer than many other regions in the Arctic
basin. Ice is a crucial habitat and source of particular food web dynamics, the loss of which will affect also a number of
mammalian and avian predatory species. The particularly pronounced physical changes of Arctic ice conditions as already
observed and expected for the coming decades, will require careful ecological monitoring. Eventually measures will be
needed to maintain or restore, to the extent possible the resilience of the Arctic populations to changing environmental
conditions.
Introduction
Over many past millennia, most of the Eurasian part of the Arctic Basin, and in particular the high seas area in the Arctic
Ocean (the waters beyond the 200 nm zones of coastal states, i.e. Norway, Russia, USA, Canada and Greenland/Denmark)
have been permanently ice covered. However, in recent years, much of the multiyear permanent pack ice has been
replaced by seasonal (1 year) ice. In addition, the former fast pack-ice is now increasingly broken up by leads. This
structural change in the Arctic ice quality will result in a substantial increase in light penetrating the thin ice and water
column, in conjunction with the overall warming of surface waters and increased temperature and salinity stratification
due to the melting of ice.
Some models predict that before the end of the century the permanent ice cover may disappear completely (Anisimov et
al., 2007). The reduction and possible loss of permanent ice cover will result in significant changes in the structure and
dynamics of the high Arctic ecosystems (CAFF, 2010; Gradinger, 1995; Piepenburg, 2005; Renaud et al., 2008;
Wassmann, 2008, 2011).
Understanding and studying the area proposed as EBSA is of particular scientific relevance as already envisaged by the
Arctic Council (Gill et al., 2011; Mauritzen et al., 2011). Such studies may in the long-term, become relevant for the
commercial exploitation of resources.
Location
The Ecologically or Biologically Significant Marine Area (EBSA) proposed focuses on the presently permanently icecovered waters in the OSPAR/NEAFC maritime areas, including the high seas section in the Central Arctic Basin north
of the 200 nm zones of coastal states, and the area of contiguous seasonal ice directly connected to the multi-year
permanent ice (see Fig. 1 attached). Therefore, the boundaries proposed extend from the North Pole (northernmost point
of OSPAR/NEAFC maritime areas) to the southern limit of the summer sea ice extent and marginal ice zone, including
on the shelf of East Greenland.
The proposal currently only relates to features of the water column and the ice surface itself. Two legal states have to be
distinguished: the Central Arctic high seas waters north of the 200 nm zones of adjacent coastal states, generally north of
84° N, and the waters within the Exclusive Economic Zones of Greenland, Russia and the fisheries protection zone of
Norway around Svalbard. Figure 1 distinguishes between the high seas beyond national jurisdiction for which the ”Joint
OSPAR/NEAFC/CBD Scientific Workshop on the Identification of Ecologically or Biologically Significant Marine
Areas (EBSAs) in the North-East Atlantic“ had a mandate23 and national/nationally administered waters within the 200
nm zone (national EEZs), within which the OSPAR Contracting Parties have the competence to report candidate EBSAs
to the Convention on Biodiversity EBSA repository (OSPAR Commission, 2011).
Participant Briefing for a Joint OSPAR/NEAFC/CBD Scientific Workshop on the Identification of Ecologically or
Biologically Significant Marine Areas (EBSAs) in the North-East Atlantic. Invitation Annex 2, 2011
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The seafloor of the respective region will likely fall on the extended continental shelves of several coastal states. It belongs
to the ”Arctic Basin“ region of (Gill et al., 2011). Seafloor features were not considered in this assessment.
Figure 1 shows the location of the Arctic Ice „Ecologically or Biologically Significant Area“ (EBSA) proposed.
Feature description
The Ecologically or Biologically Significant Marine Area (EBSA) proposed focusses on the presently permanently icecovered waters in the OSPAR/NEAFC maritime areas, including the high seas section in the Central Arctic Basin north
of the 200 nm zones of coastal states, and the marginal ice zone (where the ice breaks up, also called seasonal ice zone)
along its southern margins (see Fig. 1 attached). Due to the inflow of Atlantic water along the shelf of Svalbard, and the
concurrent outflow of polar water and ice on the Greenland side of Fram Strait, the southern limit of the summer sea ice
extent is much further south in the western compared to the eastern Fram Strait, and in former times extended all along
the Greenland coast.
Several of the key ecosystem functions and species dependencies are associated with the ice front. Statements made
about those functions and dependencies apply to the area where the front is located at any particular time of the year, and
not necessarily to either areas fully ice covered (permanently or seasonally) or open waters distant from the ice front in
summer.
The high seas section of the OSPAR maritime area in the Central Arctic ocean is generally north of 84° N and much is
fully ice-covered also in summer, although the quantity of multiyear ice has already substantially decreased and the 1year ice leaves increasingly large leads and open water spaces. The ice overlays a very deep water body of up to 5000 m
depth distinct from the surrounding continental shelves and slopes of Greenland and the Svalbard archipelago. The
Nansen-Gakkel Ridge, a prolongation of the Mid-Atlantic Ridge north of the Fram Strait is structuring the deep Arctic
basin in this section, separating the Central Nansen Basin to the south from the Amundsen Basin to the north. Abundant
hydrothermal vent sites have been discovered on this ridge at about 85° 38 N (Edmonds et al., 2003).
North of Spitsbergen, the Atlantic water of the West Spitsbergen Current enters the Arctic basin as a surface current. At
around 83° N, a deep-reaching frontal zone separates the incoming Atlantic and shelf waters from those of the Central
Nansen Basin (Anderson et al., 1989), a transition reflected in ice properties, nutrient concentrations, zooplankton
communities, and benthic assemblages (Hirche and Mumm, 1992, and literature quoted). This water subsequently
submerges under the less dense (less salinity, lower temperature) polar water and circulates, in opposite direction to the
surface waters and ice, counterclockwise along the continental rises until turning south along the Lomonossov Ridge and
through Fram Strait as East Greenland Current south to Danmark Strait (Aagaard, 1989; Aagaard et al., 1985). Connecting
the more fertile shelves with the deep central basin, these modified Atlantic waters supply the waters north of the NansenGakkel Ridge, in the Amundsen basin, with advected organic material and nutrients which supplement the autochtonous
production (Mumm et al., 1998). Due to the import of organic biomass from the Greenland Sea and the Arctic continental
shelves, part of which may not be kept in the food web due to the polar conditions, the Arctic Ocean may also represent
an enormous carbon sink (Hirche and Mumm, 1992).
In the Fram Strait, the region between Svalbard to the east and Greenland to the west, the East Greenland Current is the
main outflow of polar water and ice from the Arctic Basin (Maykut, 1985) (Aagaard and Coachman, 1968). The polar
front (0° C isotherm and 34.5 isohaline at 50 m depth) extends approximately along the continental shelf of Greenland,
separating the polar surface water from the Arctic (Intermediate) water and the marginal ice zone to the east (e.g. Aagaard
and Coachman, 1968; Paquette et al., 1985). The ice cover is densest in polar water, its extent to the east depends on the
wind conditions (compare also Angelen et al., 2011; Wadhams, 1981).
The seasonal latitudinal progression of increasing and diminishing light levels, respectively, is the determining factor for
the timing of the phytoplankton-related pelagic production. Therefore, the spring bloom and ice break up progress from
south to north in spring, reaching the Arctic area by about June/July. Because the currents in Fram Strait move in opposite
direction, the polar East Greenland Current to the south, and the Atlantic West Spitsbergen Current to the north, there is
a delay of about a month between biological spring and summer between the polar and the Atlantic side (Hirche et al.,
1991). Therefore, sea ice and the effect of melting ice are important determinants of the ecosystem processes all along
the East Greenland polar front from the Greenland Sea through Fram Strait to the Arctic Basin (Legendre et al., 1992;
Wassmann, 2011).
Ice situation
The Arctic Ocean is changing towards a one-year instead of a multi-year sea-ice system with consequences for the entire
ecosystem, including ecosystem shifts, biodiversity changes, water mass modifications, and role in the global overturning
circulation. At its maximum, sea-ice covers 4.47 million km² in the Arctic Basin (Gill et al., 2011): According to data
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from ice satellite observations in 1973-76 (NASA, 1987, in (Gill et al., 2011)), permanent ice occupied 70-80% of the
Arctic Basin area, and the inter-annual variability of this area did not exceed 2%. Seasonal ice occupied 6-17% (before
the melting period of the mid-1970s). By the end of the first decade of the 21st century, the permanent-ice area had
decreased greatly, concurrent with a rapid increase in seasonal- ice. Whereas multiyear ice used to cover 50-60% of the
Arctic, it covered less than 30% in 2008, after a minimum of 10% in 2007. The average age of the remaining multiyear
ice is also decreasing from over 20 % being at least six years in the mid- to late 1980s, to just 6% of ice six years old or
older in 2008.
Figure 2: Modelled ice age distribution in 1985-2000 (left) compared to February 2008 (right) (CAFF, 2010).
This trend is likely to amplify in the coming years, as the net ocean-atmosphere heat output due to the current anomalously
low sea ice coverage has approximately tripled compared to previous years, suggesting that the present sea ice losses have
already initiated a positive feedback loop with increasing surface air temperatures in the Arctic (Kurtz et al., 2011).
About 10% of the sea ice in the Arctic basin is exported each year through Fram Strait into the Greenland Sea (Maykut,
1985) which is therefore major sink for Arctic sea ice (Kwok, 2009). From 2001 to 2005, the summer ice cover was so
low on the East Greenland shelf, that it was more of a marginal ice zone (Smith Jr and Barber, 2007). However the
subsequent record lows in overall Arctic ice cover brought about an increase in ice cover off Greenland, which minimised
the extent of the North East Water Polynia on the East Greenland shelf24, a previously seasonally ice-free stretch of water
(Wadhams, 1981).
Ice related biota
An inventory of ice-associated biota covering the entire Arctic presently counts over 1000 protists, and more than 50
metazoan species (Bluhm et al., 2011). The regionally variable ice fauna (dependent on, inter alia, ice age, thickness,
origin) consists of sympagic biota living within the caverns and brine channels of the ice, and associated pelagic fauna.
The most abundant and diverse sympagic groups of the ice mesofauna in the Arctic seas are amphipods and copepods.
Polar cod (Boreogadus saida) and to a lesser extent Arctic cod (Arctogadus glacialis) are dependent on the sympagic
macro- and mesofauna for food. The fish themselves are important food sources for Arctic seals (such as ringed seal
Phoca hispida) and birds, for example black guillemots Cephus grylle (Bradstreet and Cross, 1982; Gradinger and Bluhm,
2004 and literature reviewed; Horner et al., 1992; Süfke et al., 1998).
The higher the light level in the ice, the higher is the biomass of benthic algae as well as meiofauna and microorganisms
within the ice (Gradinger et al., 1991). Decreasing snow cover induces a feedback loop with enhanced algal biomass
increasing the heat absorption of the ice which leads to changes in the ice structure, and ultimately the release of algae
from the bottom layer (Apollonio, 1961 in Gradinger et al., 1991). Because of the distance to land and shelves, and the
thickness and internal structure of the multiyear pack ice over deeper water, this type of ice has a fauna of its own (Carey,
1985; Gradinger et al., 1991). Arctic multiyear ice floes can have very high algal biomasses in the brine channels and in
the bottom centimeters which serves as food for a variety of proto- and metazoans, usually smaller than 1 mm, over deep
water (Gradinger et al., 1999). In the central Arctic, ice algal productivity can contribute up to 50 % of the total primary
productivity, with lower contributions in the sea ice covered margins (Bluhm et al., 2011).
In the boundary layer between ice floes and the water column, another specific community exists which forms the link
between the ice based primary production and the pelagic fauna (Gradinger, 1995). Large visible bands of diatoms hang
down from the ice, and are exploited by amphipods such as Gammarus wilkitzki, and occasionally by water column
copepods such as Calanus glacialis, which are important prey of for example polar cod Boreogadus saida. The caverns,
wedges and irregularities of the ice provide important shelter from predators for larger ice associated species and provide
an essential habitat for these species (Gradinger and Bluhm, 2004).
During melt, the entire sympagic ice biota are released into the water column where they may initiate the spring algal
plankton bloom (Smith and Sakshaug, 1990) or they may sink to the sea floor and serve as an episodic and first food pulse
for benthic organisms before pelagic production begins (Arndt and Pavlova, 2005). In particular the shallow shelves and
the shelf slope benthos has been shown to profit of this biomass input, reflected in very rich benthic communities
(Klitgaard and Tendal, 2004; Piepenburg, 2005).
The role of the polar front and marginal ice zone for the production system
Primary production in the Arctic Ocean is primarily determined by light availability, which is a function of ice thickness,
ice cover, snow cover, light attenuation), the abundance of both ice algae and phytoplankton, nutrient availability and
surface water stratification. Generally, the spring bloom occurs later further north and in regions with a thick ice and snow
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cover. The current production period in the Arctic Ocean may extend to 120 days per year, with a total annual primary
production in the central Arctic Ocean of probably up to 10 g C m-2 (Wheeler et al., 1996).
Ice algae start primary production when light levels are relatively low, as melting reduces the thickness of the ice and
snow cover. The major phytoplankton bloom develops only after the ice breaks up, when melting releases the ice biota
into the water column and meltwater leads to surface stratification. The bloom lasts a few weeks, fuelling the higher
trophic food web of the Arctic (Gradinger et al., 1999, and literature quoted).
The marginal ice zones, i.e. where the ice gets broken up in warmer Atlantic or Arctic water, play an important role in
the overall production patterns of the Arctic Ocean. Due to the strong water column stratification and increased light
levels involved with the melting of the ice, the location and recession of the ice edge in spring and summer determines
the timing and magnitude of the spring phytoplankton bloom, which is generally earlier than in the open water (Gradinger
and Baumann, 1991; Smith Jr. et al., 1987). Wind- or eddy-induced upwelling in the marginal ice zone, as well as
biological regeneration processes replenish the surface nutrient pool and therefore prolong the algal growth period
(Gradinger and Baumann, 1991; Smith, 1987). The hydrographic variability explains the patchy patterns of primary and
secondary production observed, as well as consequently the patchy occurrence of predators.
The polar front separates to some degree the pelagic faunas of the polar and Arctic waters in the Greenland Sea and Fram
Strait, each characterised by a few dominant copepod species with different life history strategies (Hirche et al., 1991;
see also review in Melle et al., 2005): In polar waters, Calanus glacialis uses under ice plankton production and lipid
reserves for initiating its spring reproduction phase, but depends on the phytoplankton bloom for raising its offspring (e.g.
Leu et al., 2011). Somewhat later, on the warm side of the polar front in Arctic water, the Atlantic species Calanus
finmarchicus uses the ice edge-related phytoplankton bloom for secondary production. Calanus hyperboreus, the third
and largest of the charismatic copepod species has its core area of distribution in the Arctic waters of the Greenland Sea
(Hirche, 1997; Hirche et al., 2006).
Zooplankton of the Arctic Basin
Overall zooplankton biomass decreases towards the central Arctic basin, reaching a minimum in the most northerly
waters, i.e. the region with permanent ice cover (Mumm et al., 1998). However, investigations in recent years
demonstrated increased biomasses compared to studies several decades earlier - possibly a consequence of the decrease
in ice thickness and cover which only enabled the investigations to take place from ship board.
There is a south-north decrease in zooplankton biomass, with a sharp decline north of 83°N (Hirche and Mumm, 1992),
coinciding with differences in the species composition of the biomass-forming zooplankton species. Whereas the southern
Nansen basin plankton is dominated by the Atlantic species Calanus finmarchicus, entering the Arctic Basin with the
West Spitsbergen Current, the northernmost branch of the North Atlantic current, the Arctic and polar species Calanus
hyperboreus and C. glacialis dominate the biomass in the high-Arctic Amundsen and Makarov Basins (Auel and Hagen,
2002; Mumm et al., 1998). The zooplankton species communities generally can be differentiated according to their
occurrence in Polar Surface Water (0-50 m, temperature below –1.7°C, salinity less than 33.0), Atlantic Layer (200–900
m; temperature 0.5–1.5°C); salinity 34.5–34.8) and Arctic Deep Water (deeper than 1000 m, temperature -0,5--1° C,
salinity > 34.9) (Auel and Hagen, 2002; Grainger, 1989; Kosobokova, 1982). The polar surface community in the upper
50 m of the water column consists of original polar species as well as species emerging from deeper Atlantic waters,
altogether leading to a high abundance and biomass peak in summer. Diversity and biomass are minimal in the
impoverished Arctic basin deepwater community (Kosobokova 1982). Apart from a limited exchange with the Atlantic
Ocean via the Fram Strait, the central Arctic deep-sea basins are isolated from the rest of the world ocean deepsea fauna.
Therefore, the bathypelagic fauna consists of a few endemic Arctic species and some species of Atlantic origin. Due to
the separation of the Eurasian and Canadian Basins by the Lomonosov Ridge, significant differences in hydrographic
parameters (Anderson et al. 1994) and in the zooplankton composition occur between both basins (Auel and Hagen,
2002).
Fish
Polar cod, Boreogadus saida, is a keystone species in the ice-related foodwebs of the Arctic. Due to schooling behavior
and high energy content polar cod efficiently transfer the energy from lower to higher trophic levels, such as seabirds,
seals and some whales (Crawford and Jorgenson, 1993).
Seabirds
Ice cover is a physical feature of major importance to marine birds in high latitude oceans, providing access to resources,
and refuge from aquatic predators (Hunt, 1990). As seabirds are dependent on leads between ice floes or otherwise open
water to access food, they search for the most productive waters in polynias (places within the ice which are permanently
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ice free) and marginal ice zones (Hunt, 1990). Here they forage both on the pelagic and sympagic ice-related fauna,
especially the early stages of polar cod and the copepods Calanus hyperboreus and C. glacialis. Likely, they benefit from
the structural complexity and good visibility of their prey near the ice (Hunt, 1990).
In the Greenland Sea and Fram Strait, major breeding colonies exist on Svalbard, Greenland and on Jan Mayen, all of
these within reach of the seasonally moving marginal ice zone or a polynia (North East Water Polynia on the East
Greenland shelf). Breeding seabirds like Little auks (Alle alle), from colonies in the northern Svalbard archipelago feed
their offspring with prey caught in the vicinity of the nests, however intermittently travel at least 100 km to the marginal
ice zone at 80° N to replenish their body reserves (Jakubas et al., Online 03 June 2011). Therefore, the distance of the
marginal ice zone to the colony site is a critical factor determining the breeding success (e.g. Joiris and Falck, 2011).
Opportunistically, the birds also use other zooplankton aggregations such as a in a cold core eddy in the Greenland Sea,
closer to the nesting site (Joiris and Falck, 2011).
A synopsis of seabird data for the period 1974–1993 (Joiris, 2000) showed that the little auk is one of the most abundant
species, together with the fulmar Fulmarus glacialis, kittiwake Rissa tridactyla and Brünnich’s guillemot Uria lomvia in
the European Arctic seas (mainly the Norwegian and Greenland Seas). In the Greenland Sea and the Fram Strait, little
auks represented the main species in polar waters, at the ice edge and in closed pack ice, reaching more than 50% of all
bird species (Joiris and Falck, 2011). In spring and autumn, millions of seabirds pass through the area when migrating
between their breeding sites on Svalbard or the Russian Arctic and their wintering areas in Canada (Gill et al., 2011).
There are several seabird species in the European Arctic which are only met in ice-covered areas, for example the Ivory
gull Pagophila eburnea and the Thick-billed guillemot Uria lomvia (see e.g. CAFF, 2010): Both species spend the entire
year in the Arctic, and breed in close proximity to sea ice although Thick-billed guillemots were observed to fly up to 100
km from their colonies over open water to forage at the ice edge (Bradstreet 1979). The relatively rare Ivory gulls are
closely associated with pack-ice, favouring areas with 70 – 90% ice cover near the ice edge, where they feed on small
fish, including juvenile Arctic cod, squid, invertebrates, macro-zooplankton, carrion, offal and animal faeces (e.g. OSPAR
Commission, 2009b). Ivory gulls have a low reproductive rate and breeding only takes place if there is sufficient food,
which makes the population highly vulnerable to the effects of climate warming (e.g. OSPAR Commission, 2009b).
Thick-billed guillemots are relatively long lived and slow to reproduce and has a low resilience to threats including oil
pollution, by-catch in and competition with commercial fisheries operations, population declines due to hunting –
particularly in Greenland (OSPAR Commission, 2009c).
Ivory gull and Thick-billed guillemots are both listed by OSPAR as being under threat and/or decline, (OSPAR
Commission, 2008) and in 2011 recommendations for conservation action were agreed (OSPAR Commission, 2011)
which will be implemented in conjunction with the circumpolar conservation actions of CAFF (CAFF, 1996; Gilchrist et
al., 2008).
Marine mammals
Several marine mammal species permanently associate with sea ice in the European Arctic. These include polar bear,
walrus, and several seal species: bearded, Erignathus barbatus; ringed, Pusa hispida; hooded, Cystophora cristata; and
harp seal Pagophilus groenlandicus. Three whale species also occupy Arctic waters year- round – narwhal, Monodon
monoceros; beluga whale, Delphinapterus leucas; and bowhead whale, Balaena mysticetus.
Polar bears Ursus maritimus are highly specialized for and dependent on the sea ice habitat and are therefore particularly
vulnerable to changes in sea ice extent, duration and thickness. They have a circumpolar distribution limited by the
southern extent of sea ice. Three subpopulations of polar bears occur in the European high Arctic: the East Greenland,
Barents Sea and Arctic Basin sub-populations, all with an unknown population status (CAFF, 2010). Following the youngof-the-year ringed seal distribution, polar bears are most common close to land and over the shelves, however some also
occur in the permanent multi-year pack ice of the central Arctic basin (Durner et al., 2009). Due to low reproductive rates
and long lifetime, it has been predicted that the polar bears will not be able to adapt to the current fast warming of the
Arctic and become extirpated from most of their range within the next 100 years (Schliebe et al., 2008).
Walruses, Odobenus rosmarus, inhabit the Arctic ice year-round. They are conservative benthic feeders, diving to 80100 m depth for scaping off the rich mollusc fauna of the continental shelves, and need ice floes as resting and nursing
platform close to their foraging grounds. Walruses have been subject to severe hunting pressure from the end of the 18th
century to the mid-20th century, and are still hunted today in Greenland (NAMMCO). By 1934, the estimated 7000080000 individuals of the Atlantic population were reduced to 1200-1300, with none left on Svalbard (Weslawski et al.,
2000). Today’s relatively small sub-populations on the East Greenland and Svalbard-Franz Josef Land coasts have
recently shown a slightly increasing trend, in the latter case reflecting the full protection of the species since the 1950´s
(CAFF, 2010; NAMMCO). Apart from their sensitivity to direct human disturbance and pollution, it is expected that
walruses will suffer from the changing ice conditions (location, thickness for being used as haul-out site) as well as
changes in ice-related productivity.
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The Atlantic subspecies of the bearded seal, Erignathus barbatus occurs south of 85° N from the central Canadian Arctic
east to the central Eurasian Arctic, but no population estimates exist (Kovacs, 2008b). Because of their primarily benthic
feeding habits they live in ice covered waters overlying the continental shelf. They are typically found in regions of broken
free-floating pack ice; in these areas bearded seals prefer to use small and medium sized floes, where they haul out no
more than a body length from water and they use leads within shore-fast ice only if suitable pack ice is not available
(Kovacs, 2008b, and literature quoted).
The Arctic ringed seal Pusa (Phoca) hispida hispida has a very large population size and broad distribution, however,
there are concerns that future changes of Arctic sea ice will have a negative impact on the population, some of which
have already been documented in some parts of the subspecies range (Kovacs et al., 2008). As the other seals, the ringed
seal uses sea ice exclusively as their breeding, moulting and resting (haulout) habitat, and feed on small schooling fish
and invertebrates. In a co-evolution with one of their main predators, the polar bear, they developed the ability to create
and maintain breathing holes in relatively thick ice, which makes them well adapted to living in fully ice covered waters
the year round.
The West Ice (or Is Odden) to the west of Jan Mayen, at approx. 72-73° N, in early spring a stretch of more of less fast
drift ice, is of crucial importance as a whelping and moulting area for harp seals and hooded seals (summarised e.g. by
ICES, 2008). Discovered in the early 18th century, up to 350000 seals (1920s) were killed per year, decimating the
populations from an estimated one million individuals in the 1950s (Ronald et al., 1982) to today´s 70000 and 243000 of
hooded and harp seals, respectively (Kovacs, 2008a, c).
Hooded seal, Cystophora cristata, is a pack ice species, which is dependent on ice as a substrate for pupping, moulting,
and resting and as such is vulnerable to reduction in extent or timing of pack ice formation and retreat, as well as ice edge
related changes in productivity (Kovacs, 2008a, and literature quoted). Hooded Seals feed on a wide variety of fish and
invertebrates, including species that occur throughout the water column. After breeding and moulting on the West Ice
they follow the retreating pack ice to the north, but also spend significant periods of time pelagically, without hauling out
(Folkow and Blix 1999) in (Kovacs, 2008a). The northeast Atlantic breeding stock has declined by 85-90 % over the last
40-60 years. The cause of the decline is unknown, but very recent data suggests that it is on-going (30% within 8 years),
despite the protective measures that have been taken in the last few years. The species is therefore considered to be
vulnerable (Kovacs, 2008a).
Harp seals Pagophilus (Phoca) groenlandicus are the most numerous seal species in the Arctic seas. Their reproduction
takes place in huge colonies, for example on the pack ice of the ‘‘West Ice’’ north of Jan Mayen, and after the breeding
season they follow the retreating pack ice edge northwards up to 85° N, feeding mainly on polar cod under the ice (Kovacs,
2008c) .
Narwhals Monodon monoceros primarily inhabit the ice-covered waters of the European Arctic, including the ice sheet
off East Greenland (Jefferson et al., 2008b). For two months in summer, they visit the shallow fjords of East Greenland,
spending all the rest of the year offshore, in deep ice-covered waters along the continental slope in the Greenland Sea
and Arctic Basin (Heide-Jørgensen and Dietz, 1995). Narwhals are deep diving benthic feeders and forage on fish, squid,
and shrimp, especially Arctic fish species, such as Greenland halibut, Arctic cod, and polar cod at up to 1500 m depth
and mostly in winter. A recent assessment of the sensitivity of all Arctic marine mammals to climate change ranked the
narwhal as one of the three most sensitive species, primarily due to its narrow geographic distribution, specialized feeding
and habitat choice, and high site fidelity (Laidre et al. 2008 in (Jefferson et al., 2008b)).
Bowhead whales Balaena mysticetus are found only in Arctic and subarctic regions and a Svalbard-Barents population
occurs from the coast of Greenland across the Greenland Sea to the Russian Arctic. They spend all of their lives in and
near openings in the pack ice feeding on small to medium-sized zooplankton. They migrate to the high Arctic in summer,
and retreat southward in winter with the advancing ice edge (Moore and Reeves 1993 in (Reilly et al., 2008)). Whaling
has decimated the original bowhead whale populations to be rare nowadays, listed by OSPAR as being under threat and/or
decline (OSPAR Commission, 2008). The species is considered to be very sensitive to changes in the ice-related
ecosystem as well as sound disturbance, possible consequences of a progressive reduction of ice cover (OSPAR
Commission, 2009a).
Belugas Delphinapterus leucas prefer coastal and continental shelf waters with a broken-up ice cover. They have never
been surveyed around Svalbard. Pods numbering into the thousands are sighted irregularly around the archipelago, and
pods ranging from a few to a few hundred individuals are seen regularly (Gjertz and Wiig 1994; Kovacs and Lydersen
2006 in (Jefferson et al., 2008a)).
Little is known about the populations of the larger fauna in the Central Arctic Basin over the deepsea basins and ridges.
But it is not likely that it is currently an area of great abundance - too far from the coastal nesting sites of marine birds,
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and over too deep water to allow feeding on benthos, as most of the larger mammals would need, and currently of too
low plankton production to feed the large whales. All of these groups have their distribution center along the continental
shelves presently - however, following the receding ice edge out to the central Arctic basin may be one of the options for
the future.
Feature condition, and future outlook
This high Arctic region is particularly vulnerable to the the loss of ice cover and other effects of the anticipated global
warming, including elevated UV radiation levels (Agustí, 2008). (Wassmann et al., 2010) summarise what changes may
be expected within the subarctic/Arctic region:
•
•
•
•
•
northward displacement (range shifts) of subarctic and temperate species, and cross-Arctic transport of
organisms;
increased abundance and reproductive output of subarctic species, decline and reduced reproductive success of
some Arctic species associated with the ice and species now preyed upon by predators whose preferred prey
have declined;
increased growth of some subarctic species and primary producers, and reduced growth and condition of animals
that are bound to, associated with, or born on the ice;
anomalous behaviour of ice-bound, ice-associated, or ice-born animals with earlier spring events and delayed
fall events;
changes in community structure due to range shifts of predators resulting in changes in the predator–prey
linkages in the trophic network.
(Wassmann, 2008) expects radical changes in the productivity, functional relationships and biodiversity of the Arctic
Ocean. He suggests that a warmer climate with less ice cover will result in greater primary production, a reduction of the
stratified water masses to the south, changes in the relationship between biological processes in the water column and the
sediments, a reduction in niches for higher trophic levels and a displacement of Arctic by boreal species. On the shelves,
increased sediment discharges are expected to lower the primary production due to higher turbidity, and enhance the
organic input to the deep ocean. A more extensive review of expected or suspected consequences of climate change for
the marine system of the Arctic is given in (Loeng et al., 2005).
Figure 3, extracted from (Gill et al., 2011), presents the conceptual ideas about possible Arctic ecosystem changes
mediated by human impact:
The normal situation shown in the upper left panel consists of ice-dependent species and species that tolerate a broader
range of temperatures and are found in waters with little or no sea ice. Primary production occurs in phytoplankton (small
dots in the figure) in ice-free waters and in ice-attached algae and phytoplankton in ice-covered waters. Phytoplankton
(small t-shaped symbols in the figure) and ice algae are the main food sources for zooplankton and benthic animals. The
fish community consists of both pelagic and demersal species. Several mammals are ice-associated, including polar bears
and several species of seals. A number of sea bird species are also primarily associated with ice-covered waters.
At moderate temperature increases (upper right) populations of ice-dependent species are expected to decline as sea ice
declines, and sub-Arctic species are expected to move northwards. Arctic benthic species are expected to decline,
especially if their distributions are pushed close to or beyond the continental slope.
The expected effects from fisheries relate to the continental shelves. Two major effects are changes in populations of
benthic organisms due to disturbance from bottom trawling and removal of large individuals in targeted fish stocks. In
addition, the size of targeted stocks, both demersal and pelagic, may be reduced.
In addition, the effects of ocean acidification are considered (lower right). Ocean acidification will result in depletion of
carbonate phases such as aragonite and calcite. This will alter the structure and function of calcareous organisms,
particularly at lower trophic levels. Changes in pH can also alter metabolic processes in a range of organisms. It is not
known how these changes will propagate to higher trophic levels, but the effects could be substantial.
Figure 3: Conceptual models showing potential impacts on Arctic marine ecosystems under different scenarios (Gill et
al., 2011).
Gill et al. (2011) conclude that the central part of the Arctic Basin is not a region for fisheries or oil and gas exploration.
However, this region has played and will continue to play a very important role in the redistribution of pollutants, due to
ice drift and/or currents between coastal and shelf areas and the Arctic Basin peripheries, far from sources of pollution.
ICES Advice 2013, Book 1
317
Assessment against CBD EBSA Criteria
Table 1
CBD
Criterion
Relation of each of the CBD criteria to the proposed area relating to the best available science. Note that a
candidate EBSA may qualify on the basis of one or more of the criteria, the boundaries of the EBSA need
not be defined with exact precision.
EBSA Description
Uniqueness or
rarity
The area contains either (i) unique (“the only one of its
kind”), rare (occurs only in few locations) or endemic
species, populations or communities, and/or (ii) unique, rare
or distinct, habitats or ecosystems; and/or (iii) unique or
unusual geomorphological or oceanographic features
Ranking of criterion relevance
(please mark one column with an X)
Don’t Know Low
Some
High
x
Explanation for ranking
Arctic sea ice, in particular the multiyear ice of the Central Arctic is globally unique and hosts endemic species such as the Gammarid
amphipod Gammarus wilkitzki and sea ice meiofauna which will disappear with the melting of the ice. Polar bears, walrusses, bowhead
whales, narwhales, belugas, several seal species and many bird species are endemic to the high Arctic ice.
While sea ice species such as G. wilkitzki are not endemic to the proposed EBSA they are endemic to the Arctic and unique within the
OSPAR area
Special importance Areas that are required for a population to survive and thrive
for life-history
stages of species
x
Explanation for ranking
Sea ice is essential for its sympagic fauna, and to some extent also for the pelagic associated fauna which also depends on the right
timing of biomass production (match/mismatch with bloom periods). The marginal ice zone and other openings in the ice are essential
feeding grounds for a large number of ice-associated species which exploit the seasonally high production there.
At present the area covered by the proposed EBSA includes both the area of permanent ice and, the area covered by seasonal ice and
the ice edge. The community associated with the ice edge requires it special structural features for a number of ecological processes,
including increased primary and secondary productivity, and feeding and resting of seabirds and marine mammals.
Area containing habitat for the survival and recovery of
x
Importance for
endangered, threatened, declining species or area with
threatened,
significant assemblages of such species
endangered or
declining species
and/or habitats
Explanation for ranking
The high arctic ice hosts endemic species such as the Gammarid amphipod Gammarus wilkitzki and sea ice meiofauna which will
disappear with the melting of the ice. Many of the obligatory ice-related species are listed as vulnerable by IUCN, and/or listed as
under threat and/or decline by OSPAR, examples include the Ivory gull, thick-billed guillemot, bowhead whale, hooded seal and polar
bear. With the overall trend of retreating sea ice extent, the proposed EBSA may become increasingly important for all ice-dependent
species in the future.
Areas that contain a relatively high proportion of sensitive
Vulnerability,
habitats, biotopes or species that are functionally fragile
fragility,
sensitivity, or slow (highly susceptible to degradation or depletion by human
activity or by natural events) or with slow recovery
recovery
318
x
ICES Advice 2013, Book 1
Explanation for ranking
The ice-related foodweb and ecosystem is highly sensitive to the ecological consequences of a warming climate. Beyond this the Arctic
is at the forefront of the impacts of ocean acidification (Wicks & Roberts 2012). The largest changes in ocean pH will occur in the
Arctic Ocean, with complete undersaturation of the Arctic Ocean water column predicted before the end of this century (Steinacher et
al. 2009). Many of the seabird and mammal populations are particularly sensitive to changes due to their already low population
numbers, and low fertility. If the retreat of the ice to the north will lead to increased shipping and oil and gas exploitation in Arctic
waters, the increased risk of spills would also pose a potential hazard for example for guillemots, which are extremely susceptible to
mortality from oil pollution (CAFF, 2010). In addition, some species like Ivory gull are sensitive to an increased heavy metal load in
their prey.
Biological
productivity
Area containing species, populations or communities with
comparatively higher natural biological productivity
Explanation for ranking
This criterion was not evaluated in the OSPAR/NEAFC/CBD Workshop. ICES did not have enough information to evaluate this
criterion.
Biological diversity Area contains comparatively higher diversity of ecosystems,
habitats, communities, or species, or has higher genetic
diversity
Explanation for ranking
This criterion was not evaluated in the OSPAR/NEAFC/CBD Workshop. ICES did not have enough information to evaluate this
criterion.
References
Aagaard, K., 1989. A synthesis of Arctic Ocean circulation. Rapport Proces et Verbeaux Réunion du Conseil international
pour l'Exploration de la Mer 188, 11-22.
Aagaard, K., Coachman, L.K., 1968. The East Greenland Current north of Denmark Strait: Part II. Arctic 21, 267-290.
Aagaard, K., Swift, J.H., Carmack, E.C., 1985. Thermohaline circulation in the Arctic mediterranean seas. Journal of
Geophysical Research 90, 4833-4846.
Agustí, S., 2008. Impacts of increasing ultraviolet radiation on the polar oceans. In: Impacts of global warming on polar
ecosystems. Duarte, C.M. (Ed.) Fundación BBVA pp. 25-46.
Anderson, L.G., Jones, E.P., Koltermann, K.P., Schlosser, P., Swift, J.H., Wallace, D.W.R., 1989. The first oceanographic
section across the Nansen Basin in the Arctic Ocean. Deep Sea Research 36, 475-482.
Angelen, J.H.v., Broeke, M.R.v.d., Kwok, R., 2011. The Greenland Sea Jet: A mechanism for wind‐driven sea ice export
through Fram Strait. Geophysical Research Letters 38 (L12805).
Anisimov, O.A., Vaughan, D.G., Callaghan, T.V., Furgal, C., Marchant, H., Prowse, T.D., Vilhjálmsson, H., Walsh, J.E.,
2007. Polar regions (Arctic and Antarctic). In: Climate Change 2007: Impacts, Adaptation and Vulnerability.
Contribution of Working Group II to the Fourth Assessment Report of the Intergovernmental Panel on Climate
Change. Parry, M.L., Canziani, O.F., Palutikof, J.P., Linden, P.J.v.d., Hanson, C.E. (Eds.)Cambridge University
Press, Cambridge pp. 653-685.
Arndt, C., E. , Pavlova, O., 2005. Origin and fate of ice fauna in the Fram Strait and Svalbard area. Marine Ecology
Progress Series 301, 55-66.
Auel, H., Hagen, W., 2002. Mesozooplankton community structure, abundance and biomass in the central Arctic Ocean.
Marine Biology 140, 1013-1021.
Bluhm, B.A., Gebruk, A.V., Gradinger, R., Hopcroft, R.R., Huettmann, F., Kosobokova, K.N., Sirenko, B.I., Weslawski,
J.M., 2011. Arctic marine biodiversity: An update of species richness and examples of biodiversity change.
Oceanography 24 (3), 232-248.
Bradstreet, M.S.M., Cross, W.E., 1982. Trophic relationships at high Arctic ice edges. Arctic 35 (1), 1-12.
CAFF, 1996. International Murre conservation strategy and action plan. CAFF International Secretariat, CAFF
Circumpolar Seabird Working Group, Akureyri, Iceland, pp. 1-16.
CAFF, 2010. Arctic Biodiversity Trends 2010. Selected indicators of change. CAFF International Secretariat, , Akureyri,
Iceland.
Carey, A.G.I., 1985. Marine Ice Fauna. In: Arctic Sea Ice Biota. A., H.R. (Ed.)CRC Press, Boca Raton. Florida pp. 17190
Crawford, R.E., Jorgenson, J.K., 1993. Schooling behaviour of arctic cod, Boreogadus saida in relation to drifting pack
ice. Environmental Biology of Fishes 36 (4), 345-357.
Durner, G.M., Douglas, D.C., Nielson, R.M., Amstrup, S.C., McDonald, T.L., Stirling, I., Mauritzen, M., Born, E.W.,
Wiig, Ø., Deweaver, E., Serreze, M.C., Belikov, S.E., Holland, M.M., Maslanik, J., Aars, J., Bailey, D.A.,
Derocher, A.E., 2009. Predicting 21st-century polar bear habitat distribution from global climate models.
Ecological Monographs 79 (1), 25-58.
ICES Advice 2013, Book 1
319
Edmonds, H.N., Michael, P.J., Baker, E.T., Connelly, D.P., Snow, J.E., Langmuir, C.H., Dick, H.J.B., Mühe, R., German,
C.R., Graham, D.W., 2003. Discovery of abundant hydrothermal venting on the ultraslow-spreading Gakkel ridge
in the Arctic Ocean. Nature 421, 252-256.
Gilchrist, G., Strøm, H., Gavrilo, M.V., Mosbech, A., 2008. International Ivory Gull conservation strategy and action
plan. CAFF International Secretariat, Circumpolar Seabird Group (CBird). CAFF Technical Report No. 18.
Gill, M.J., Crane, K., Hindrum, R., Arneberg, P., Bysveen, I., Denisenko, N.V., Gofman, V., Grant-Friedman, A.,
Gudmundsson, G., Hopcroft, R.R., Iken, K., Labansen, A., Liubina, O.S., Melnikov, I.A., Moore, S.E., Reist, J.D.,
Sirenko, B.I., Stow, J., Ugarte, F., Vongraven, D., Watkins, J., 2011. Arctic Marine Biodiversity Monitoring Plan
(CBMP-MARINE PLAN), CAFF Monitoring Series Report No.3, April 2011. CAFF International Secretariat,,
Akureyri, Iceland.
Gradinger, R., 1995. Climate change and biological oceanography of the Arctic Ocean. Phil. Trans. R. Soc. A 352, 277286.
Gradinger, R., Bluhm, B.A., 2004. In situ observations on the distribution and behavior of amphipods and Arctic cod
(Boreogadus saida) under the sea ice of the high Arctic Canadian Basin. Polar Biology 27, 595-603.
Gradinger, R., Friedrich, C., Spindler, M., 1999. Abundance, biomass and composition of the sea ice biota of the
Greenland Sea pack ice. Deep Sea Research 46, 1457-1472.
Gradinger, R., Spindler, M., Henschel, D., 1991. Development o Arctic sea-ice organisms under graded snow cover. In:
Proceedings of the Pro Mare Symposium on Polar Marine Ecology. Sakshaug, E., E., H.C.C., Øritsland, N.A.
(Eds.), Polar Research 10 (1), Trondheim pp. 295-307.
Gradinger, R.R., Baumann, M.E.M., 1991. Distribution of phytoplankton communities in relation to the large-scale
hydrographical regime in the Fram Strait. Mar. Biol. 111, 311-321.
Grainger, E.H., 1989. Vertical distribution of zooplankton in the central Arctic Ocean. In: Proc 6th Conf Comite´Arctique
Int 1985. Rey, L., Alexander, V. (Eds.) Brill Leiden pp. 48–60.
Heide-Jørgensen, M.P., Dietz, R., 1995. Some characteristics of narwhal, Monodon monoceros, diving behaviour in
Baffin Bay. Canadian Journal of Zoology 73, 2106-2119.
Hirche, H.J., 1997. Life cycle of the copepod Calanus hyperboreus in the Greenland Sea. Marine Biology 128 (4), 607618.
Hirche, H.J., Baumann, M.E.M., Kattner, G., Gradinger, R., 1991. Plankton distribution and the impact of copepod
grazing on primary production in Fram Strait, Greenland Sea. Journal of Marine Systems 2 (3-4), 477-494.
Hirche, H.J., Mumm, N., 1992. Distribution of dominant copepods in the Nansen Basin, Arctic Ocean, in summer. Deep
Sea Research Part A. Oceanographic Research Papers 39 (2, Part 1), S485-S505.
Hirche, H.J., Muyakshin, S., Klages, M., Auel, H., 2006. Aggregation of the Arctic copepod Calanus hyperboreus over
the ocean floor of the Greenland Sea. Deep Sea Research Part I: Oceanographic Research Papers 53 (2), 310-320.
Horner, R., Ackley, S.F., Dieckmann, G.S., Gulliksen, B., Hoshiai, T., Legendre, L., Melnikov, I.A., Reeburgh, W.S.,
Spindler, M., Sullivan, C.W., 1992. Ecology of sea ice biota. Habitat, terminology, and methodology. Polar
Biology 12 (3), 417-427.
Hunt, G.L.J., 1990. The pelagic distribution of marine birds in a heterogeneous environment. Polar Research 8, 43-54.
ICES, 2008. Report of the ICES Advisory Committee In: ICES Advice, Book 3, The Barents and the Norwegian SEa.
Jakubas, D., Iliszko, L