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Transcript 
Curriculum Vita
Tommy D. Dickey
Ocean Physics Laboratory
University of California, Santa Barbara
6487 Calle Real, Suite A
Goleta, CA 93117
Phone: 805 893-7354
FAX: 805 967-5704
Email: [email protected]
Website: http://www.opl.ucsb.edu
Education
B.S./B.A. Physics/Math, Ohio University, 1968
M.S. Physics, Stevens Institute of Technology, 1972 (completed while in U.S. Coast Guard)
M.A. Geophysical Fluid Dynamics, Princeton University, 1975
Ph.D. Geophysical Fluid Dynamics, Princeton University, 1977
Positions Held
Instructor, U.S. Coast Guard (military service: taught electronics and human relations), 1969-1973
Part-time Instructor Math and Physics, New York Institute of Technology, 1972-1973
Research Assistant, Geophysical Fluid Dynamics Laboratory, Princeton University, 1973-1977
Rosenstiel Fellow, Rosenstiel School of Marine and Atmospheric Science, University of Miami, 1977-1978
Professor (Assistant to Full), Department of Geological Sciences, Institute for Marine and Coastal Studies,
Hancock Institute for Marine Sciences, University of Southern California (USC), 1978-1996
Co-Director & Co-Founder of USC’s Hancock Institute for Marine Sciences
(with Patricia Kremer), 1995-1996
Professor (VII-Off-scale) Department of Geography and Graduate Program in Marine Sciences, University
of California, Santa Barbara, 1996-present
Cumulative List of Publications
1
YR
1978
2
1979
3
1980
4
1981
5
1981
6
1981
7
1983
8
1983
TITLE and AUTHOR
“A note on the effect of zonal boundaries on equatorial
waves,” Dickey, T.D.
“The Kolmogoroff ‘r2/3 law’", Dickey, T.D. and G.L.
Mellor
“Decaying turbulence in neutral and stratified fluids,”
Dickey, T.D. and G.L. Mellor
“The relationship between downward irradiance and
upper ocean structure,” Simpson, J.J. and T.D. Dickey
“Alternative parameterizations of downward irradiance
and their dynamical significance,” Simpson, J.J. and T.D.
Dickey
Elements of Oceanography Study Guide, Pipkin, B.W.,
D.S. Gorsline, D.J. Bottjer, and T.D. Dickey.
PUBLISHER
J. Geophys. Res., 73,
3675-3678
Phys. Fluids, 22,
1029-1032
J. Fluid Mech., 99,
13-31
J. Phys. Ocean., 11,
309-323
J. Phys. Ocean., 11,
876-882
CATEGORY
Refereed
Article
Refereed
Article
Refereed
Article
Refereed
Article
Refereed
Article
Star Publishing Co.,
61pp
“The sensitivity of upper ocean structure to time varying
wind direction,” Dickey, T.D. and J.J. Simpson
“The influence of optical water type on the diurnal
response of the upper ocean,” Dickey, T.D. and J.J.
Simpson
Geophys. Res. Lett.,
10, 133-136.
Tellus, 35, 142-151
Unrefereed
Study Guide
Book
Refereed
Article
Refereed
Article
1
9
1984
10
1984
11
1984
12
1984
13
1984
14
1984
15
1986
16
1986
17
1986
18
1986
19
1987
20
1987
21
1988
22
1988
23
1988
24
1989
25
1989
26
1989
27
1989
“A laboratory technique for investigating the relationship
between gas transfer and fluid turbulence,” Dickey, T.D.,
B. Hartman, D. Hammond, and E. Hurst
“Observations and simulation of a bottom Ekman layer
on a continental shelf,” Dickey, T.D. and J.C. Van Leer
“Measurement of fluid flow using streak photography,”
Dickey, T.D., B. Hartman, E. Hurst, and S. Isenogle
Gas Transfer at Water
Surfaces, 93-100
Refereed Book
Chapter
J. Geophys. Res., 89,
1983-1988
Amer. J. Physics, 52,
216-219
Refereed
Article
Refereed
Article
“An offshore eddy in the California Current System:
Preface,” Simpson, J.J., C.J. Koblinsky, L.R. Haury, and
T.D. Dickey
“An offshore eddy in the California Current System: Part
I, Interior dynamics,” Simpson, J.J., T.D. Dickey, and
C.J. Koblinsky
“An offshore eddy in the California Current System: Part
II, Surface manifestation,” Koblinsky, C.J., J.J. Simpson,
and T.D. Dickey
“Variability of net longwave radiation over the eastern
North Pacific Ocean,” Siegel, D.A. and T.D. Dickey
“Observations of optical features associated with
thermohaline structures,” Dickey, T.D., D.A. Siegel, A.
Bratkovich, and L. Washburn
Prog. in Oceanogr.,
13, 1-4
Refereed
Article
Prog. in Oceanogr.,
13, 5-50
Refereed
Article
Prog. in Oceanogr.,
13, 51-69
Refereed
Article
J. Geophys. Res., 91,
7657-7666
Ocean Optics, VIII,
308-313
Refereed
Article
Unrefereed
Article
“The Biowatt bio-optical and physical moored
measurement program,” Dickey, T., E. Hartwig, and J.
Marra
“Effects of sensor characteristics on the inferred vertical
structure of the diffuse attenuation coefficient spectrum,”
Siegel, D.A., C.R. Booth, and T.D. Dickey
“Observations of the vertical structure of the diffuse
attenuation coefficient spectrum,” Siegel, D.A. and T.D.
Dickey
“On the parameterization of irradiance for ocean
photoprocesses,” Siegel, D.A. and T.D. Dickey
“Recent advances and future directions in multidisciplinary in situ oceanographic measurement
systems,” Dickey, T.D.
EOS, 67, 650
Unrefereed
Article
Ocean Optics, VIII,
115-124
Unrefereed
Article
Deep-Sea Res., 34,
547-563
Refereed
Article
J. Geophys. Res., 92,
14,648-14,662
Toward a Theory on
Biological-Physical
Interactions in the
World Ocean, 555598
Oceanic Processes in
Marine Pollution, 5,
43-48
Ocean Optics, IX, 6774
EOS, 70, 82-85
Refereed
Article
Refereed Book
Chapter
“Physical and biological variability near the White's
Point ocean outfall,” Siegel, D., B. Jones, T. Dickey, I.
Haydock, and A. Bratkovich
“Characterization of downwelling spectral irradiance
fluctuations,” Siegel, D.A. and T.D. Dickey
“GLOBEC - Global Ecosystem Dynamics,” GLOBEC
Editorial Committee
“Simulated behavior of drilling mud discharges off
southern California,” Brandsma, M., R. Kolpack, T.
Dickey, and B. Balcom
“The physical basis for recruitment variability in fish
populations,” Rothschild, B.J., T.R. Osborn, T.D.
Dickey, and D.M. Farmer
“Optical determination of particulate abundance and
production variations in the oligotrophic ocean,” Siegel,
D.A., T.D. Dickey, L. Washburn, M.K. Hamilton, and
B.G. Mitchell
2
Oceanic Processes in
Marine Pollution, 6,
169-186
Journal du Conseil
Intern. de l'Explor. de
la Mer, 45, 136-145
Deep-Sea Res., 36,
211-222
Refereed Book
Chapter
Unrefereed
Article
Unrefereed
Article
Refereed Book
Chapter
Refereed
Article
Refereed
Article
28
1989
29
1990
30
1990
31
1990
32
1990
33
1990
34
1990
35
1990
36
1990
37
1990
38
1991
39
1991
40
1991
41
1991
42
1991
“Isopycnal mixing and the distribution of optical
properties across the North Pacific Subtropical Front,”
Washburn, L., D.A. Siegel, T.D. Dickey, and M.K.
Hamilton
“Nutrients and mixing, chlorophyll, and phytoplankton
growth,” Marra, J., Bidigare, R.R., and T.D. Dickey
“Evidence for phytoplankton succession and chromatic
adaptation in the Sargasso Sea during springtime 1985,”
Bidigare, R.R., J. Marra, T.D. Dickey, R. Iturriaga, K.S.
Baker, R.C. Smith, and H. Pak
“Mesoscale eddy diffusion, particle sinking, and the
interpretation of sediment trap data,” Siegel, D.A., T.C.
Granata, A.F. Michaels, and T.D. Dickey
“Meridional variations of the springtime phytoplankton
community in the Sargasso Sea,” Siegel, D.A., R.
Iturriaga, R.R. Bidigare, R.C. Smith, H. Pak, T.D.
Dickey, J. Marra, and K.S. Baker
“Variability of physical, chemical, and biological
parameters in the vicinity of an ocean outfall plume,”
Jones, B., A. Bratkovich, T. Dickey, G. Kleppel, A.
Steele, R. Iturriaga, and I. Haydock
“Physical-optical-biological scales relevant to
recruitment in large marine ecosystems,” Dickey, T.D.
“The physical strength of marine snow and its
implications for particle disaggregation processes in the
ocean,” Alldredge, A.L., T.C. Granata, C.C. Gotshalk,
and T.D. Dickey
“Diel variations of bio-optical properties in the Sargasso
Sea,” Hamilton, M., T.C. Granata, T.D. Dickey, J.D.
Wiggert, D.A. Siegel, J. Marra, and C. Langdon
“Time series observations of bio-optical properties in the
upper layer of the Sargasso Sea,” Dickey, T. Granata, M.
Hamilton, J. Wiggert, J. Marra, C. Langdon, and D.A.
Siegel
“Moored systems for time series observations of biooptical and physical variability in the coastal zone,”
Dickey, T.D. and D.V. Manov
“Global survey of bio-optical properties,” Marra, J., T.
Dickey, and J. Mueller
“The fluid mechanics of copepod feeding in a turbulent
flow: a theoretical approach,” Granata, T.C. and T.D.
Dickey
“Concurrent high resolution bio-optical and physical
time series observations in the Sargasso Sea during the
spring of 1987,” Dickey, T., J. Marra, T. Granata, C.
Langdon, M. Hamilton, J. Wiggert, D. Siegel, and A.
Bratkovich
“The emergence of concurrent high resolution physical
and bio-optical measurements in the upper ocean and
their applications,” Dickey, T.
3
Deep-Sea Res., 36,
1607-1620
Refereed
Article
Deep-Sea Res., 37,
127-143
Mar. Ecol. Progr.
Ser., 60, 113-122
Refereed
Article
Refereed
Article
J. Geophys. Res., 95,
5305-5311.
Refereed
Article
J. Mar. Res., 48,
379-412
Refereed
Article
Stratified Flows,
877-890
Refereed Book
Chapter
Large Marine
Ecosystems: Patterns,
Processes, and
Yields, 82-98
Limnol. and
Oceanogr., 35, 14151428
Refereed Book
Chapter
Ocean Optics, X,
214-224
Unrefereed
Article
Ocean Optics, X,
202-213
Unrefereed
Article
Proc. of Seventh
Symp. on Coastal and
Ocean Management,
86-100
EOS, 72, 577, 581
Unrefereed
Article
Refereed
Article
Progr. in Oceanogr.,
26, 243-261
Unrefereed
Article
Refereed
Article
J. Geophys. Res., 96,
8643-8663
Refereed
Article
Rev. of Geophys., 29,
383-413
Refereed
Article
“Short-term variations of the bio-optical properties of the
ocean in response to cloud-induced irradiance
fluctuations,” Stramska, M. and T.D. Dickey
“Estimation of seasonal primary production from moored
optical sensors in the Sargasso Sea,” Marra, J., T.
Dickey, W.S. Chamberlin, C. Ho, T. Granata, D.A.
Kiefer, C. Langdon, R. Smith, R. Bidigare, and M.
Hamilton
“Variability of bio-optical properties in the upper ocean
associated with diel cycles in phytoplankton population,”
Stramska, M. and T.D. Dickey
“Mixing, dispersion, and resuspension in the vicinity of
an ocean wastewater plume,” Washburn, L., B.H. Jones,
A. Bratkovich, T.D. Dickey, and M.-S. Chen
“Seasonal variability of bio-optical and physical
properties in the Sargasso Sea,” Dickey, T., T. Granata,
J. Marra, C. Langdon, J. Wiggert, Z. Chai-Jochner, M.
Hamilton, J. Vazquez, M. Stramska, R. Bidigare, and D.
Siegel
“An experiment in duplex communication with a multivariable moored system in coastal waters,” Dickey, T.D.,
R.H. Douglass, D. Manov, and D. Bogucki
“Estimates of local vorticity in mesoscale systems,”
Granata, T., T. Dickey, M. Estrada, and A. Castellon
43
1992
44
1992
45
1992
46
1992
47
1993
48
1993
49
1993
50
1993
51
1993
52
1993
53
1993
54
1993
55
1993
GLOBEC Report No. 3, Sampling and Observing
Systems, Dickey, T. (ed.)
56
1994
57
1994
“Determination of longwave heat flux at the air-sea
interface using measurements from buoy platforms,”
Dickey, T., D. Manov, R. Weller, and D. Siegel
“Modeling phytoplankton dynamics in the northeast
Atlantic during the initiation of the spring bloom,”
Stramska, M. and T. Dickey
“Phytoplankton bloom and the vertical thermal structure
of the upper ocean,” Stramska, M. and T. Dickey
“The effect of temporal undersampling on primary
production estimates,” Wiggert, J., T. Dickey, and T.
Granata
“Automated in situ observations of upper ocean
biogeochemistry, bio-optics, and physics and their
potential use for global studies,” Dickey, T.D., T.C.
Granata, and I. Taupier-Letage
“Technology and related developments for
interdisciplinary global studies,” Dickey, T.
U.S. JGOFS Planning Report: Bio-optics in U.S.
JGOFS,” Dickey, T. and D. Siegel (eds.)
4
J. Geophys. Res., 97,
5713-5721
Refereed
Article
J. Geophys. Res., 97,
7399-7412
Refereed
Article
J. Geophys. Res., 97,
17,873-17,887
Refereed
Article
J. Hydraul. Eng., 118,
38-58
Refereed
Article
J. Geophys. Res., 98,
865-898
Refereed
Article
J. Atmos. Ocean.
Tech, 10, 637-644
Refereed
Article
Mixing in
Geophysical Flows,
71-82
J. Mar. Res., 51,
819-842
J. Geophys. Res., 99,
3361-3371
Refereed Book
Chapter
Proc. of the Ocean
Climate Data
Workshop, 317-352
Unrefereed
Article
Sea Technology,
August, 1993, 47-53
U.S. JGOFS Planning
and Coordination
Office, Woods Hole
Oceanographic
Institution, 180pp
GLOBEC
International,
Chesapeake
Biological
Laboratory, 99pp
J. Atmos. and
Oceanic Tech., 11,
1057-1078
J. Geophys. Res., 99,
10,241-10,253
Unrefereed
Article
Planning
Report
Refereed
Article
Refereed
Article
Planning
Report
Refereed
Article
Refereed
Article
58
1994
59
1994
60
1995
61
1995
62
1995
63
1995
64
1996
65
1996
66
1996
67
1997
68
1997
69
1997
70
1997
71
1997
72
1997
“Bio-optical and physical variability in the sub-arctic
North Atlantic Ocean during the spring of 1989,”
Dickey, T., J. Marra, M. Stramska, C. Langdon, T.
Granata, R. Weller, A. Plueddemann, and J. Yoder
“Light scattering induced by turbulent flow,” Bogucki,
D, A. Domaradzki, R. Zaneveld, and T. Dickey
“The vertical structure of the upper ocean during the
Marine Light-Mixed Layer experiment,” Plueddemann,
A.J., R.A. Weller, M. Stramska, T.D. Dickey, and J.
Marra
J. Geophys. Res., 99,
22,541-22,556
Refereed
Article
Ocean Optics, XII,
247-255
J. Geophys. Res.,
100, 6605-6619
Unrefereed
Article
Refereed
Article
“Bio-optical variability associated with phytoplankton
dynamics in the North Atlantic,” Stramska, M., T.
Dickey, J. Marra, A. Plueddemann, C. Langdon, and R.
Weller
“Trapped near-inertial waves and enhanced chlorophyll
distributions,” Granata, T., J. Wiggert, and T. Dickey
“Zooplankton variability on the equator at 140° W during
the JGOFS EqPac study,” Roman, M.R., H.G. Dam, A.L.
Gauzens, J. Urban-Rich, D.G. Foley, and T.D. Dickey
“A decade of interdisciplinary process studies,” Dickey,
T. and B.H. Jones
“Emerging technologies in biological, chemical, optical,
and physical sampling of the ocean,” Dickey, T.
J. Geophys. Res.,
100, 6621-6632
Refereed
Article
J. Geophys. Res.,
100, 20,793-20,804
Deep-Sea Res. II, 42,
673-693
Refereed
Article
Refereed
Article
Ocean Optics, XIII,
254-259
International
Workshop on
Biological and
Chemical Data
Management,
Hamburg, Germany,
Proc. of the N. Amer.
Water and Environ.
Cong.
Unrefereed
Article
Unrefereed
Article
EOS, 78, 117, 120121
Unrefereed
Article
J. Phys. Oceanogr.,
27, 1181-1196
Refereed
Article
GLOBEC
International Special
Contributions, No. 2
Sea Technology,
April, 81-86
J. Geophys. Res.,
102, 25,061-25,071
Planning
Report
NOAA Technical
Report NESDIS 87,
115-124
Unrefereed
Report
“Comparison of near-field dilutions from in situ
measurements and simulated dilutions at the Sand Island,
HI sewage outfall plume,” Petrenko, A.A., B.H. Jones,
T.D. Dickey, and P.J.W. Roberts
“Moored instruments weather Arabian Sea monsoons
yield data,” Rudnick, D.L., R.A. Weller, C.C. Eriksen,
T.D. Dickey, J. Marra, and C. Langdon
“Sediment resuspension and mixing through resonantlygenerated internal solitary waves,” Bogucki, D., T.
Dickey, and L. Redekopp
“An Advanced Modeling/Observation System (AMOS)
for Physical-Biological-Chemical Ecosystem Research
and Monitoring,” Robinson, A.R. and T.D. Dickey (eds.)
“Bermuda sensor system testbed, Dickey, T.D., D. Frye,
H.W. Jannasch, E. Boyle, and A.H. Knap
“Effects of a sewage plume on the biology, optical
characteristics, and particle size distributions of coastal
waters,” Petrenko, A.A., B.H. Jones, T.D. Dickey, M.
LeHaitre, and C. Moore
“Emerging interdisciplinary technologies in biological,
chemical, optical, and physical sampling of the oceans,”
Dickey, T.
5
Unrefereed
Article
Unrefereed
Article
Refereed
Article
73
1997
“Uses of offshore platforms,” Dickey, T.
Role of Offshore
Platforms in
Environmental &
Coastal Research, 50
pp., Nansen
Environmental &
Remote Sensing
Center & the
University of Bergen
Unrefereed
Report
74
1998
75
1998
The Sea, Chapter 14,
367-398
Mon. Weather Rev.,
126, 1195-1201
Refereed Book
Chapter
Refereed
Article
76
1998
J. Hydraul. Eng., 124,
565-571
Refereed
Article
77
1998
Deep-Sea Res. I, 45,
771-794
Refereed
Article
78
1998
Deep-Sea Res. I, 45,
1393-1410
Refereed
Article
79
1998
Deep-Sea Res. II, 44,
1801-1826
Refereed
Article
80
1998
Deep-Sea Res. II, 45,
2001-2025
Refereed
Article
81
1998
Geophys. Res. Lett.,
25, 3533-3536
Refereed
Article
82
1998
Nature, 394, 263-266
Refereed article
83
1998
Ocean Optics, XIV
Unrefereed
Article
84
1998
“Current and water property measurements in the coastal
ocean,” Dickey, T., A. Plueddemann, and R. Weller
“Upper-ocean temperature response to Hurricane Felix as
measured by the Bermuda Testbed Mooring,” Dickey, T.,
D. Frye, J. McNeil, D. Manov, N. Nelson, D. Sigurdson,
H. Jannasch, D. Siegel, T. Michaels, and R. Johnson
“Shape and near-field dilution of the Sand Island sewage
plume: observations compared to model results,”
Petrenko, A.A., B.H. Jones, and T.D. Dickey
“Initial results from the Bermuda Testbed Mooring
Program,” Dickey, T., D. Frye, H. Jannasch, E. Boyle, D.
Manov, D. Sigurdson, J. McNeil, M. Stramska, A.
Michaels, N. Nelson, D. Siegel, G. Chang, J. Wu, and A.
Knap
“Short-term variability of the underwater light field in
the oligotrophic ocean in response to surface waves and
clouds,” Stramska, M. and T.D. Dickey
“Longwaves and primary production in the central
equatorial Pacific at 0, 140°W,” Foley, D.G., T.D.
Dickey, M.J. McPhaden, R.R. Bidigare, M.R. Lewis,
R.T. Barber, S.T. Lindley, C. Garside, D.V. Manov, and
J.D. McNeil
“Seasonal variability of bio-optical and physical
properties in the Arabian Sea: October 1994 - October
1995,” Dickey, T., J. Marra, D.E. Sigurdson, R.A.
Weller, C.S. Kinkade, S.E. Zedler, J.D. Wiggert, and C.
Langdon
“Sediment resuspension in the wakes of Hurricanes
Edouard and Hortense,” Dickey, T.D., G.C. Chang, Y.C.
Agrawal, A.J. Williams, 3rd, and P.S. Hill
“Influence of mesoscale eddies on new production in the
Sargasso Sea,” McGillicuddy, D.J., A.R. Robinson, D.A.
Siegel, H.W. Jannasch, R. Johnson, T.D. Dickey, J.D.
McNeil, A.F. Michaels, and A.H. Knap
“High temporal resolution spectral absorption
measurements during the Coastal Mixing and Optics
experiment,” Chang, G.C. and T.D. Dickey
“Report of the First Ocean-Systems for Chemical,
Optical, and Physical Experiments (O-SCOPE)
Workshop,” Dickey, T., N. Bates, R. Byrne, F. Chavez,
R. Feely, C. Moore, and R. Wanninkhof
Report of the First
Ocean-Systems for
Chemical, Optical,
and Physical
Experiments (OSCOPE) Workshop
Workshop
Report
6
85
1998
“Internal solitary waves and optical variability during
the Coastal Mixing and Optics experiment,” G. Chang,
Dickey, T., J. McNeil, M. Levine, L. Redekopp, D.
Bogucki, and T. Boyd
Ocean Optics, XIV
Unrefereed
Article
86
1998
Deep-Sea Res. II, 45,
2253-2267
Refereed
Article
87
1999
“Variability in primary production as observed from
moored sensors in the central Arabian Sea in 1995,”
Marra, J., T.D. Dickey, C. Ho, C.S. Kinkade, D.E.
Sigurdson, R.A. Weller, and R.T. Barber
“Report of the Second Ocean-Systems for Chemical,
Optical, and Physical Experiments (O-SCOPE)
Workshop,” Dickey, T., R. Feely, R. Wanninkhof, F.
Chavez, N. Bates, R. Byrne, E. Kaltenbacher, and C.
Moore
Workshop
Report
88
1999
Report of the Second
Ocean-Systems for
Chemical, Optical,
and Physical
Experiments (OSCOPE) Workshop
J. Geophys. Res.,
104, 15,537-15,548
89
1999
Appl. Optics, 38,
3876-3887
Refereed
Article
90
1999
Deep-Sea Res. II, 47,
1813-1832
Refereed
Article
91
1999
Unrefereed
article
92
1999
“Report of the First HyCODE Data Management and
Distribution Workshop,” Dickey, T., S. Ackleson, R.
Arnone, P. Bissett, J. Donovan, S. Glenn, W. Hou, W.
McBride, O. Schofield, J. Smart, and W. Snyder
93
1999
“Towards new platform technology for sustained
observations,” Griffiths, G., R. Davis, C. Eriksen, D.
Frye, P. Marchand, and T. Dickey
94
1999
“Real-time forecasting of the multidisciplinary coastal
ocean with the Littoral Ocean Observing and Predicting
System (LOOPS),” Robinson, A.R., J.G. Bellingham, C.
Chryssostomidis, T.D. Dickey, E. Levine, N.
Petrikalakis, D.L. Porter, B.J. Rothschild, H. Schmidt, K.
Sherman, D.V. Holliday, and D.K. Atwood
WHOI/ONR Internal
Solitary Wave
Workshop, eds. T.F.
Duda and D.M.
Farmer, Woods Hole
Technical Report
WHOI-99-07, 65-68
Report of the First
HyCODE Data
Management and
Distribution
Workshop
OCEAN OBS 99,
Intern. Conf. on the
Ocean Observing
System for Climate,
Saint-Raphael,
France
Proceedings of the
Third Conference on
Coastal Atmospheric
and Oceanic
Prediction Processes,
New Orleans, LA,
American
Meteorological
Society
“New chemical, bio-optical, and physical observations of
upper ocean response to the passage of a mesoscale eddy
off Bermuda,” McNeil, J.D., H.W. Jannasch, T. Dickey,
D. McGillicuddy, M. Brzezinski, and C.M. Sakamoto
“Partitioning in situ total spectral absorption by use of
moored spectral absorption-attenuation meters,” Chang,
G.C. and T.D. Dickey
“Diel bio-optical variability in the Arabian Sea as
observed from moored sensors,” Kinkade, C.S., J. Marra,
T.D. Dickey, C. Langdon, D.E. Sigurdson, and R. Weller
“Preliminary observations of optical variability
associated with internal solitary waves during the Coastal
Mixing and Optics experiment,” Chang, G.C. and T.D.
Dickey
7
Refereed
Article
Workshop
Report
Unrefereed
Article
Unrefereed
Article
“LOOPS Massachusetts Bay Sea trial preliminary data
report and data inventory: August - October 1998,”
Robinson, A.R., J. Bellingham, T. Dickey, A.
Gangopadhyay, D.V. Holliday, E. Levine, D. Porter, and
K. Sherman
“Oceanographic time-series observatories,” Send, U., R.
Weller, S. Cunningham, C. Eriksen, T. Dickey, M.
Kawabe, R. Lukas, M. McCartney, and S. Osterhus,
95
1999
96
1999
97
1999
“Recent advances in interdisciplinary technologies,”
Dickey, T.
98
2000
99
2000
100
2000
101
2000
102
2000
103
2000
104
2000
105
2000
“Autosub experiment near Bermuda,” Griffiths, G., A.
Knap, and T. Dickey
“Internal tidal effects on sewage plume near Sand Island,
HI,” Petrenko, A.A., B.H. Jones, T.D. Dickey, and P.
Hamilton
“A seasonal succession of physical-biological interaction
mechanisms in the Sargasso Sea,” Wiggert, J., T.
Granata, T. Dickey, and J. Marra
“Operational observation networks for ports, a large
estuary, and an open shelf,” Glenn, S.M., W. Boicourt,
B. Parker, and T.D. Dickey
“Long-term real-time coastal ocean observation
networks,” Glenn, S.M., T.D. Dickey, B. Parker, and W.
Boicourt
“The northeast monsoon's impact on mixing,
phytoplankton biomass, and nutrient cycling in the
Arabian Sea,” Wiggert, J., B. Jones, T. Dickey, K. Brink,
R. Weller, J. Marra, and L.A. Codispoti,
“Emerging interdisciplinary technologies and their
potential utilization in the Global Ocean Observing
System,” Dickey, T.
“Chemical sensor technology - Current and future
applications,” Tokar, J.M. and T.D. Dickey
106
2000
“Interdisciplinary observations from moorings and
autonomous underwater vehicles: recent advances and a
look toward the future,” T. Dickey
8
LOOPS MBST-98
Data Report, Harvard
University, Boston,
MA, 1999
Data Report
OCEAN OBS 99
Intern. Conf. on the
Ocean Observing
System for Climate,
Saint-Raphael,
France, October 1822, 1999
OCEAN OBS 99
Intern. Conf. on the
Ocean Observing
System for Climate,
Saint-Raphael,
France, October 1822, 1999
Sea Tech., February
2000
Cont. Shelf Res., 20,
1-13
Unrefereed
Article
J. Mar. Res., 57, 933966
Refereed
Article
Oceanography, 13,
12-23
Refereed
Article
Oceanography, 13,
24-34
Refereed
Article
Deep-Sea Res. II, 47,
1353-1385
Refereed
Article
Oceanology 2000,
Brighton, UK, March,
2000
Chemical Sensors in
Oceanography,”
Gordon and Breach
Scientific Publishers,
Amsterdam, 303-329,
2000
The Eastern
Mediterranean
Climatic Transient,
Its Origin, Evolution
and Impact on the
Ecosystem, CIESM
Workshop Series,
Trieste, Italy, 47-50
Unrefereed
Article
Unrefereed
Article
Unrefereed
Article
Refereed
Article
Refereed
Book Chapter
Unrefereed
Article
107
2000
108
2000
109
2001
110
2001
111
2001
112
2001
113
2001
114
2001
115
2001
116
2001
“An intercomparison of current measurements using a
VMCM, an ADCP, and a recently developed acoustic
current meter,” Gilboy, T.P., T.D. Dickey, D.E.
Sigurdson, X. Yu, and D. Manov
“High temporal resolution optical and physical time
series data: Coastal Mixing and Optics and LEO-15,”
Chang, G., T. Dickey, O. Schofield, and P. Bissett
“A review of the NOPP Ocean-Systems for Chemical,
Optical, and Physical Experiments (O-SCOPE) project,
Dickey, T., N. Bates, R. Byrne, F. Chavez, R. Feely, C.
Moore, and R. Wanninkhof
“Optical and physical variability on time-scales from
minutes to the seasonal cycle on the New England shelf:
July 1996 - June 1997,” Chang, G.C. and T.D. Dickey
“Towards new platform technology for sustained
observations,” Griffiths, G., R. Davis, C. Eriksen, D.
Frye, P. Marchand, T. Dickey, and R. Weller
“Physical and biogeochemical variability from hours to
years at the Bermuda Testbed Mooring site: June 1994 March 1998,” Dickey, T., S. Zedler, X. Yu, S.C. Doney,
D. Frye, H. Jannasch, D. Manov, D. Sigurdson, J.D.
McNeil, L. Dobeck, T. Gilboy, C. Bravo, D.A. Siegel,
and N. Nelson.
“Sediment resuspension over a continental shelf during
Hurricanes Edouard and Hortense,” Chang, G.C., T.D.
Dickey, and A.J. Williams, 3rd
“Spectral particulate attenuation and particle size
distribution in the bottom boundary layer of a continental
shelf,” Boss, E., W.S. Pegau, W.D. Gardner, J.R.V.
Zaneveld, A.H. Barnard, M.S. Twardowski, G.C. Chang,
and T.D. Dickey
“Inherent optical properties and irradiance,” Dickey, T.
“An annual cycle of phytoplankton biomass in the
Arabian Sea, 1994-1995, as determined by moored
optical sensors,” Kinkade, C.S., J. Marra, T.D. Dickey,
and R. Weller
9
J. Atmos. Ocean.
Tech., 17, 561-574
Refereed
Article
Proc. Ocean Optics
XV, Monte Carlo,
Monaco, October.
Fifth Symposium on
Integrated Observing
Systems, Proc. Amer.
Meteorol. Soc.
J. Geophys. Res.,
106, 9435-9453.
Unrefereed
Article
Observing the Ocean
for Climate in the 21st
Century, C.J.
Koblinsky and N.R.
Smith (Eds.),
GODAE, Bureau of
Meteorology,
Australia, Melbourne,
Australia, 324-337.
Deep-Sea Res. II, 48,
2105-2140.
Refereed Book
Chapter
J. Geophys. Res.,
106, 9517-9531
Refereed
Article
J. Geophys. Res.,
106, 9509-9516.
Refereed
Article
Encyclopedia of
Ocean Sciences, J.H.
Steele, S.A. Thorpe,
and K.K. Turekian
(Eds.), Academic
Press, Orlando, 13131323.
Deep-Sea Res. II, 48,
1285-1301.
Refereed Book
Chapter
Unrefereed
Article
Refereed
Article
Refereed
Article
Refereed
Article
117
2001
“Oceanographic Timeseries Observatories,” Send, U., B.
Weller, S. Cunningham, C. Eriksen, T. Dickey, M.
Kawabe, R. Lukas, M. McCartney, and S. Osterhus, 2001
118
2001
119
2001
“Interdisciplinary ocean process studies on the New
England shelf,” Dickey, T.D. and A.J. Williams III
“Modelling water column structure and suspended
particulate matter on the Middle Atlantic continental
shelf during passage of Hurricanes Edouard and
Hortense,” Souza, A. J., T.D. Dickey, and G.C. Chang
120
2001
121
2001
122
2001
123
2001
124
2002
125
2002
126
2002
127
2002
128
2002
“The role of new technology in advancing ocean
biogeochemical research,” Dickey, T.
Note: paper was previously titled “New technologies for
JGOFS”
“Recent advances and future visions: temporal variability
of optical and bio-optical properties of the ocean,”
Dickey, T. and G. Chang; paper was formerly called
“Insights from bio-optical time series”
“For observing world's oceans: emerging sensors and
systems,” Dickey, T.
“Advances in autonomous biogeochemical
observations,” Dickey, T.
“The application of autonomous underwater vehicles for
interdisciplinary measurements in Massachusetts and
Cape Cod Bays,” Yu, X., T. Dickey, J. Bellingham, D.
Manov, and K. Streilein
“Moored observations of upper ocean response to the
monsoons in the Arabian Sea during 1994-1995,” R.
Weller, A.S. Fischer, D.L. Rudnick, C.E. Eriksen, T.
Dickey, J. Marra, C. Fox, and R. Leben
“Variability of the downwelling diffuse attenuation
coefficient with consideration of inelastic scattering,”
Zheng, X., T. Dickey, and G. Chang
“Nearshore physical processes and bio-optical properties
in the New York Bight,” Chang, G.C., T.D. Dickey, O.
Schofield, A.D. Weidemann, E. Boss, W.S. Pegau, M.
Moline, and S.M. Glenn
“Solar energy and its biological-physical interactions in
the sea,” Dickey, T. and P. Falkowski
10
Observing the Ocean
for Climate in the 21st
Century, C.J.
Koblinsky and N.R.
Smith (Eds.),
GODAE, Bureau of
Meteorology,
Australia, Melbourne,
Australia, 376-390.
J. Geophys. Res.,
106, 9427-9434
J. Mar. Res., 59,
1021-1045.
Refereed Book
Chapter
Oceanography, 14(4),
108-120.
Refereed
Article
Oceanography, 14(3),
15-29.
Refereed
Article
Sea Technology,
42(12), 10-16.
U.S. JGOFS
Newsletter, June,
2001
Cont. Shelf Res., 22,
2225-2245.
Unrefereed
Article
Unrefereed
Article
Deep Sea Res. II, 49,
2195-2230.
Refereed
Article
Appl. Opt., 41(30),
6477-6488.
Refereed
Article
J. Geophys. Res.,
107(C9), 3133,
doi:10.1029/2001JC0
01018.
The Sea, Vol. 12, Ch.
10, A. R. Robinson,
J.J. McCarthy, and
B.J. Rothschild
(Eds.), 401-440.
Refereed
Article
Refereed
Article
Refereed
Article
Refereed
Article
Refereed Book
Chapter
129
2002
“A vision of oceanographic instrumentation and
technology in the early 21st century,” T. Dickey
130
2002
“Analysis and simulations of the upper ocean's response
to Hurricane Felix at the Bermuda Testbed Mooring site:
August 13-23, 1995,” J. Zedler, S.E., T.D. Dickey, S.C.
Doney, J.F. Price, X. Yu, and G.L. Mellor, 2003
131
2002
132
2002
133
2003
134
2003
135
2003
136
2003
“Hydrographic and particle distributions over the Palos
Verdes continental shelf: spatial, seasonal, and daily
variability,” Jones, B., M. Noble, and T. Dickey, 2002
“Optical impacts on solar transmission in coastal
waters,” Chang, G.C. and T. Dickey
“The Jerlov Award of the Oceanography Society as
presented to Raymond C. Smith, November, 2002,
Introductory Remarks by T. Dickey
“Toward closure of upwelling radiance in coastal
waters,” Chang, G., T. Dickey, C.D. Mobley , E. Boss,
and W. S. Pegau
“Emerging ocean observations for interdisciplinary data
assimilation systems,” Dickey, T.
“Scientific Cabled Observatories for Time Series
(SCOTS) Report” Glenn, S. and T. Dickey (eds.)
137
2003
138
2003
139
2003
140
2003
“New sensors and systems for monitoring bio-optical and
biogeochemical changes in the ocean,” Dickey, T., C.
Moore, and O-SCOPE Team
“Optical Methods for Interdisciplinary Research in the
Coastal Ocean,” Chang, G., T. Dickey, S. Jiang, D.
Manov, and F. Spada
“Transient physical forcing of pulsed export of
bioreactive material to the deep Sargasso Sea,” Conte,
M.H., T.D. Dickey, J.C. Weber, R. Johnson, and A. Knap
“Coastal ocean optical influences on solar transmission
and radiant heating rate,” Chang, G.C. and T.D. Dickey;
[This paper was chosen as a highlight paper for JGR as
noted in EOS, Transactions of the American Geophysical
Union]
11
Oceans 2020: Science
for Future Needs, Ch.
10, J.G. Field, G.
Hempl, and C.P.
Summerhayes (Eds.),
Island Press,
Washington, DC,
209-254.
J. Geophys. Res.,
107(12), (2002), p.
25-1.
doi:10.1029/2001JC0
00969, 2002
Cont. Shelf Res.,
22(6-7), 945-965
Refereed Book
Chapter
Ocean Optics XVI,
Santa Fe
Oceanography, 16(1),
30-31
Unrefereed
Article
Unrefereed
Article
Appl. Optics, 42(9),
1574-1582
Refereed
Article
J. Mar. Syst., 40-41,
5-48.
National Science
Foundation Report,
published by
Consortium for
Oceanographic
Research and
Education, 80pp.
Sea Tech. , Oct.,
2004
Refereed
Article
Reviewed
Report
Recent Research
Developments in
Optics, eds , M.
Kawasaki, N.
Asgrriz, and R.
Anthony, Research
Signposts Publishing,
chapter 15, 249-270.
Deep-Sea Res. I,
50(10-11), 11571187.
J. Geophys. Res.,
109, C01020,
doi:1029/2003JC001
821
Refereed
Article
Refereed
Article
Refereed
Article
Unrefereed
Article
Refereed
Article
Refereed
Article
“Satellite evidence of hurricane-induced plankton
blooms in the ocean desert,” Babin, S. J.A., Carton, T.D.
Dickey, and J.D. Wiggert. This paper was a winner of the
Johns Hopkins Universitry Applied Physics Laboratory’s
award for Outstanding Research Paper in an externally
refereed publication.
“Methods for reducing biofouling on moored optical
sensors,” Manov, D., G. Chang, and T. Dickey
J. Geophys.
Res., Vol. 109, No.
C3, C03043, doi:
1029/2003JC00
1938
Refereed
Article
J. Atmos. Ocean.
Tech., 957-967, 2004.
Refereed
Article
2004
“Radiometric and bio-optical measurements form
moored and drifting buoys: measurements and data
analysis protocols,” Kuwahara, V.S., P.G. Strutton, T.D.
Dickey, M.R. Abbott, R. Letelier, M.R. Lewis, S.
McLean, F.P. Chavez, A. Barnard, and J.R. Morrison
Unrefereed
Report
144
2004
145
2004
“The expanding role of ocean color and optics in the
changing field of operational oceanography, Glenn, S.,
O. Schofield, T.D. Dickey, R. Chant, J. Kohut, H.
Barrier, J. Bosch, L. Bowers, E. Creed, C. Haldeman, E.
Hunter, J. Kerfoot, C. Mudgal, M. Oliver, H. Roarty, E.
Romana, M. Crowley, D. Barrick, and C. Jones
“Studies of coastal ocean dynamics and processes
using emerging optical technologies,” Dickey, T.
Ocean Optics
Protocols for Satellite
Ocean Color
Validation, Vol. IV,
NASA Tech. Rep.
Series
Oceanography, 17(2),
86-95
Oceanography, 17(2),
9-13
Reviewed
Article
146
2004
Oceanography, 17(2),
32-43
Reviewed
Article
147
2004
Oceanography, 17(2),
16-23
Reviewed
Article
148
2004
Oceanography, 17(2),
24-31
Reviewed
Article
149
2004
Refereed Book
Chapter
150
2004
“Tidally induced turbulence and suspended sediment,”
Souza, A., L.G. Alvarez, and T. Dickey
151
2005
“Interdisciplinary oceanographic observations: the wave
of the future,” Dickey, T.D. and R. Bidigare
NATO Advanced
Study Institute Series,
eds. T. Oguz and M.
Follows, Kluwer
Academic Publishers,
149-188.
Geophysical
Research Letters, 31,
L20309, doi:
10.1029/2004GL0211
86.
Scientia Marina,
69(Suppl. 1), 23-42.
141
2004
142
2004
143
“From meters to kilometers: A look at ocean-color scales
of variability, spatial coherence, and the need for finescale remote sensing in coastal ocean optics,” Bissett,
W.P., R.A. Arnone, C.O. Davis, T.D. Dickey, D. Dye,
D.D.R. Kohler, and R.W. Gould, Jr.
“The new age of hyperspectral oceanography,” Chang,
G., K. Mahoney, A. Briggs-Whitmore, D.D.R. Kohler,
C.D. Mobley, M. Lewis, M.A. Moline, E. Boss, M. Kim,
W. Philpot, and T.D. Dickey
“Watercolors in the coastal zone: What can we see?,”
Schofield, O., R.A. Arnone, W.P. Bissett, T.D. Dickey,
C.O. Davis, Z. Finkel, M. Oliver, and M.A. Moline
“Exploration of biogeochemical temporal variability,”
Dickey, T.
12
Reviewed
Article
Reviewed
Article
Reviewed
Article
152
2006
“Quick transport of primary produced organic carbon to
the ocean interior,” Honda, M.C., H. Kawakami, K.
Sasaoka, S. Watanabe, and T. Dickey
Geophysical
Research Letters, 33,
L166603, doi:
10.1029/2006GL0264
66.
Reviewed
Article
153
2006
“Toward a global ocean system for measurements of
optical properties using remote sensing and in situ
observations,” Chang, G., T. Dickey, T., and M. Lewis
Refereed Book
Chapter
154
2006
“Optical oceanography: recent advances and future
directions using global remote sensing and in situ
observations,” Dickey, T.D., M.R. Lewis and G.C.
Chang,
155
2006
156
2006
Marine Technology
Society
Refereed
Article
157
2006
“In situ optical variability and relationships in the Santa
Barbara Channel: Implications for remote sensing,”
Chang, G.C., A.H. Barnard, S. McLean, P.J. Egli, C.
Moores, J.R.V. Zaneveld, T.D. and A. Hanson
“The Bermuda Testbed Mooring and HALE-ALOHA
Mooring programs: Innovative Deep-Sea Global
Observations,” Dickey, T, G. Chang, C. Moore, A.
Hanson, D. Karl, D. Manov, F. Spada, D. Peters, J.
Kemp, O. Schofield, and S. Glenn
“The Jerlov Award presented to J. Ronald V. Zaneveld:
Introductory remarks,” Dickey, T.
Manual of Remote
Sensing, Volume 7,
Marine Environment,
Chapter 9 ed. J.
Gower
Reviews of
Geophysics, 44 (1),
RG 1001,
10.1029/2003RG000
148.
Applied Optics, 45
(15), 3593-3604
Oceanography, 19(4),
194
Unrefereed
Note
158
2007
McGraw-Hill,
Boston, 394p
Book
Encyclopedia of
Ocean Sciences, eds.,
J.H. Steele, S.A.
Thorpe and K.K.
Turekian, Academic
Press, in press.
Refereed Book
“Exploring the World Ocean,” Chamberlin, S. and T.
Dickey
Reviewed
Article
Refereed
Article
Work in Press
B-1
2007
“Long-term ocean monitoring and monitoring stations,”
Weller, R, T. Dickey and R. Lukas
13
B-2
2007
B-3
2007
B-4
2007
“Temporal variability of zooplankton biomass from
ADCP backscatter time series data at the Bermuda
Testbed Mooring Site,” Jiang, S., T. Dickey, D.
Steinberg and L. Madin
“Physical and biological observations of cyclones in the
lee of Maui and Hawaii,” Dickey, T., F. Nencioli, V.
Kuwahara, C. Leonard, W. Black, R. Bidigare, S. Rii,
and Q. Zhang
“Interdisciplinary sampling strategies for detection and
characterization of harmful algal blooms,” Chang, G.C.
and T.D. Dickey
Deep-Sea Res. I.
Refereed
Article
Deep-Sea Res. II,
accepted
Refereed
Article
Workshop on RealTime Systems for
Observating Coastal
Ecosystem Dynamics
and Harmful Algal
Blooms,
(HABWATCH), eds.
M. Babin, and C.
Roesler, UNESCO
Publishing.
Refereed Book
Chapter
Science, submitted
Refereed
Article
Deep-Sea Res. II
submitted
Refereed
Article
Deep-Sea Res. II
submitted
Refereed
Article
Deep-Sea Res. II,
submitted
Refereed
Article
Journal of
Geophysical
Research
in preparation
Optics Express
Refereed
Article
Work Submitted
C-1
2007
C-2
2007
C-3
2007
C-4
2007
“Eddy-induced diatom bloom produces limited carbon
export fluxes in the subtropical North Pacific Ocean,”
Benitez-Nelson, et al
“Physical and biological implications of cyclone Noah in
the lee of Hawaii during E-Flux I,” Kuwahara, V., F.
Nencioli, T. Dickey, W. Black, R. Bidigare, and S. Rii,
“Physical dynamics and biological implications of a
mesoscale eddy in the lee of Hawai'i: cyclone Opal
observations during E-Flux III,” Nencioli, F, T. Dickey,
W. Black, R. Bidigare and S. Rii
“The transient oasis: Nutrient-phytoplankton dynamics
and particle export in Hawaiian lee cyclones,” Rii, Y.,
S.L. Brown, F. Nencioli, V. Kuwahara, T. Dickey, D.M.
Karl, and R.R. Bidigare, 2007, (R)
Work in Progress
D-1
2007
“Upper ocean responses to hurricanes and tropical storms
off Bermuda,” Black, W. and T. Dickey,
D-2
2007
“Bio-optical measurements for the validation of ocean
color satellites using moored platforms of opportunity,”
Kuwahara, V.S., X. Zheng, G. Chang, S. Jiang, F.
Chavez and T. Dickey
14
Refereed
Article
D-3
2007
“Simulation of upper ocean responses to Hurricane
Fabian,” Chao, Y., T. Dickey, et al.
D-4
2007
Applications of Optics for Oceanography, Dickey, T.
and E. Boss, [Text/Reference Book is about 2/3
completed]
Geophysical
Research Letters
in preparation
Elsevier
Refereed
Article
Book
OPL instrumentation has been shown on covers of Reviews of Geophysics, August 1991, March,
2006; Sea Technology, February 1997, June 2004; Backscatter, December 1999; Oceanography, June
2004.
Lectures and Presentations since January 2000:
Month/Year
Jan./2000
Jan./2000
Jan./2000
Jan./2000
Feb./2000
Mar./2000
Apr/2000
Apr./2000
Jun./2000
Jun./2000
Jun./2000
Aug./2000
Sep./2000
Oct./2000
Nov./2000
Jan./2001
Jan./2001
Title/Date
National Academy of Sciences Workshop on Ocean
Observatories, “Autonomous interdisciplinary sampling at
the Bermuda Testbed mooring”
National Academy of Sciences Workshop on Ocean
Observatories, “Sargasso Sea Ocean Observatory,” (with
Hansell et al.)
American Meteorological Society Meeting, “Bio-optical
measurements from the Bermuda Testbed Mooring,” (with
David Sigurdson)
AGU/ASLO, 9 presentations by OPL
ONR Bioluminescence Workshop, Keynote address: “New
technologies for ocean observations”
Oceanology 2000, Keynote address: “Emerging technologies
for observing the ocean autonomously”
Jet Propulsion Laboratory Seminar, “Autonomous sampling
of the ocean with new sensor technologies and platforms”
JGOFS Synthesis Meeting, “High resolution
interdisciplinary time series observations during JGOFS”
ASLO Meeting, “Emerging sensor and platform
technologies for ocean observational systems”
NOPP O-SCOPE Workshop, “Review of the O-SCOPE
project”
Planning Workshop, “Lessons learned from the Bermuda
Testbed Mooring program,”
Fun in the Sun Day Camp, “Discovery in the oceans”
Meeting Place
Key Largo, FL
“Plans for a New BTM Surface Buoy Design Workshop,”
Woods Hole Oceanographic Institution
"The Bermuda Testbed Mooring as a mooring-ofopportunity for groundtruthing ocean color satellites,"
Oceans from Space
"Interdisciplinary time series observations around the world
oceans"
"Interdisciplinary time series observations at the LEO-15
site, 2000," HyCODE Workshop
"Review of the NOPP O-SCOPE program," American
Meteorological Society Meeting
Woods Hole, MA
15
Key Largo, FL
Anaheim, CA
San Antonio, TX
San Diego, CA
Brighton, United
Kingdom
Pasadena, CA
Bergen, Norway
Copenhagen, Denmark
Santa Barbara, CA
University of Hawaii
Santa Barbara, CA
Venice, Italy
UCLA Department of
Atmospheric Sciences
St. Petersburg, FL
Albuquerque, NM
Feb./2001
Feb./2001
Mar./2001
Mar./2001
Apr./2001
May/2001
May/2001
Jul./2001
Oct./2001
Dec./2001
Dec./2001
Jan./2002
Feb./2002
Feb./2002
Feb./2002
Mar./2002
Apr./2002
May/2002
Jun./2002
Jun. /2002
Co-convenor (with Koh Harada) of the International
Workshop on Autonomous Measurements of
Biogeochemical Parameters in the Ocean, talk: "Toward
interdisciplinary time series observations on the global scale"
Co-convenor of Workshop (with Jim McWilliams, UCLA),
"Toward a coastal observation and modeling system for
Southern California"
"Review of the Bermuda Testbed Mooring: Science and
Technologies," Sargasso Sea Ocean Observatory Workshop
"Interdisciplinary observations from autonomous platforms,"
Workshop on Time Series Observations in the North Pacific
"Review of capabilities for interdisciplinary observations as
part of the Global Ocean Observing System," Ocean
Observations Panel for Climate
"Future ocean observations for interdisciplinary data
assimilation models," invited keynote speaker for the 33rd
International Liege Colloquium on Ocean Hydrodynamics
"Recent developments in autonomous interdisciplinary
sampling," Time Series Working Group of the OOPC
"Biogeochemical Observatories," invited, B-DEOS Town
Meeting
"Autonomous interdisciplinary time series observations:
recent progress and future visions," IAPSO-IABO, 2001: An
Ocean Odyssey
"The Bermuda Testbed Mooring and Emerging Technologies
for Interdisciplinary Research," T. Dickey, invited, Fall
AGU
"Linkage between transient upper ocean physical and
biological forcing and deep ocean flux at the Bermuda timeseries site," invited, M.H. Conte, J.C. Weber, T.D. Dickey,
and D.J. McGillicuddy, Jr., Fall AGU
Convenor of 3rd HyCODE Workshop
Co-convenor (with Stan Wilson and others) of session
"Multidisciplinary Ocean Observations and Observatories,"
AGU/ASLO Meeting
"Toward global multi-disciplinary time-series observations,"
T. Dickey, AGU/ASLO Meeting
"Episodic primary production and export carbon fluxes in the
Arabian Sea," P. White, S. Honjo, T. Dickey, and R. Weller,
AGU/ASLO Meeting
"In situ primary production measurements using autonomous
sampling platforms: toward a global observational system,"
Phytoplankton Productivity
"Autonomous interdisciplinary sampling: toward a global
observational system," HOT/BATS Workshop
"Ocean exploration in time and space, " International Global
Ocean Exploration Symposium
“Review of carbon and interdisciplinary measurements for
the Global Ocean Observing System,” Steering Committee
Meeting of the Ocean Observing Panel for Climate (Global
Ocean Observing System)
Convenor of the Ocean-Systems for Chemical, Optical, and
Physical Experiments (O-SCOPE) Workshop
16
Honolulu, HI
UCSB
Bermuda Biological
Station for Research, St.
Georges, Bermuda
Tokyo, Japan
Melbourne, Australia
Liege, Belgium
Woods Hole, MA
Cardiff, Wales, United
Kingdom
Mar del Plata, Argentina
San Francisco
San Francisco
Santa Barbara
Honolulu, Hawaii
Honolulu, Hawaii
Honolulu, Hawaii
Bangor, Wales
Vancouver, BC, Canada
Paris, France
Kiel Germany
Maui, Hawaii
Jul./2002
Jul./2002
Jul./2002
Jul./2002
Aug./2002
Sep./2002
Oct./2002
Oct./2002
Oct./2002
Oct./2002
Oct./2002
Oct./2002
Nov./2002
Dec./2002
Co-convenor (with Scott Glenn) of the Steering Committee
for the NSF Scientific Cabled Observatory Time Series
(SCOTS) activity
“Exploration of Biogeochemical Variability on Time Scales
from Minutes to the Interannual, Part 1: Introduction to
Processes, Scales, and Observational Techniques,
”
Invited lecturer for the NATO Advanced Study Institute
Summer School on The Ocean Carbon Cycle and Climate
“Exploration of Biogeochemical Variability on Time Scales
from Minutes to the Interannual, Part 2: Examples of
Variability and Coupling of Physical and Biogeochemical
Processes in Several Ocean Domains
”
Invited lecturer for the NATO Advanced Study Institute
Summer School on The Ocean Carbon Cycle and Climate
“Exploration of Biogeochemical Variability on Time Scales
from Minutes to the Interannual, Part 3: Part 3: Toward the
Future: Blending of Global Observations & Models
”
Invited lecturer for the NATO Advanced Study Institute
Summer School on The Ocean Carbon Cycle and Climate
Co-convenor (with Scott Glenn), the NSF Workshop on
Scientific Cabled Observatory Time Series (SCOTS)
“Review of carbon and interdisciplinary measurements for
the Global Ocean Observing System,” Steering Committee
Meeting of the Coastal Ocean Observing System (Global
Ocean Observing System)
“Report on Scientific Cabled Observatory Time Series
(SCOTS) activity,” Steering Committee meeting of the NSF
Dynamics of Earth and Ocean Systems (DEOS) activity
“Toward Global Ocean Interdisciplinary Measurements
Using Emerging Autonomous Sampling Technologies
,” Invited lecture at the PICES Meeting
“Toward the Development of a Global Interdisciplinary
Time-series Network
,” Invited lecture at the PICES Meeting
“Bio-optical-Physical Interactions and Global
Interdisciplinary Time-series Observations
,” Invited lecture at Anhui Institute of Optics and Fine
Mechanics
“Physical-Biological-Optical Interactions and Global
Interdisciplinary Time-series Observations,”
Invited lecture at First Institute of Oceanography
“Bio-optical-Physical Interactions and Global
Interdisciplinary Time-series Observations,”
Invited lecture at Second Institute of Oceanography
“Optical impacts on solar transmission in coastal waters,” G.
Chang and T. Dickey, Ocean Optics XVI
“Global Ocean Interdisciplinary Time Series Using
Emerging
Platforms and Sensors,” invited presentation,
American Geophysical Union
17
Baltimore, MD
Ankara, Turkey,
Ankara, Turkey
Ankara, Turkey
Portsmouth, VA
Cape Town, South
Africa
Washington, DC
Qingdao, China
Qingdao, China
Hefei, China
Qingdao, China
Hangzhou, China
Santa Fe, NM
San Francisco
Jan./2003
Jan./2003
Feb./2003
Mar./2003
Mar./2003
Mar./2003
Apr./2003
Apr./2003
May/2003
Jun./2003
Jun./2003
Jun./2003
Jun./2003
Jul./2003
Jul./2003
Jul./2003
“Autonomous Sampling Methods for the Global Carbon
Observing System,” invited lecture for the International
Workshop on Ocean Carbon Observation Activities
Convenor of the Hyperspectral Coastal Ocean Dynamics
Experiment Workshop
Convenor of the NOPP Multi-disciplinary Ocean Sensors for
Environmental Analyses and Networks (MOSEAN) program
“Report on Scientific Cabled Observatory Time Series
(SCOTS) activity,” Steering Committee meeting of the NSF
Dynamics of Earth and Ocean Systems (DEOS) activity
Advisory Committee comments for the Advisory Committee
for the Mediterranean Forecast System: Toward
Environmental Predictions program
“Upper Ocean Response to Extreme Events: Coastal & Open
Ocean Case Studies,”
invited lecture for the Office of Naval Research’s Southeast
U.S. Site Review
“Review of technologies for the Eulerian Observatory
System,” meeting of the Time Series Team under the
Steering Committee of the Ocean Observing Panel for
Climate (Global Ocean Observing System)
Paris, France
“Considerations for the Development of Global
Interdisciplinary Time-series Networks
,” European Geophysical Union/American Geophysical
Union Meeting
“New Technologies and Their Roles in Advancing
Biogeochemical Science During the JGOFS Era
,” invited lecture for the Final JGOFS Open Science
Conference, A Sea of Change: JGOFS Accomplishments and
the Future of Ocean Biogeochemistry, National Academy of
Sciences
“Report on Scientific Cabled Observatory Time Series
(SCOTS) activity,” Steering Committee meeting of the NSF
Dynamics of Earth and Ocean Systems (DEOS) activity
“Scientific Cabled Observatories for Time Series (SCOTS),”
Dickey, T. and S. Glenn, The Annual Oceanography Society
Meeting and Oceanology International Americas
“Physical and chemical dynamics of coastal systems,”
Invited lecture for Workshop on Real-Time Systems for
Observing Coastal Ecosystem Dynamics and Harmful Algal
Blooms (HABWATCH)
“Overview of chemical and physical sensors,” Invited
lecture, Workshop on Real-Time Systems for Observing
Coastal Ecosystem Dynamics and Harmful Algal Blooms
(HABWATCH)
“Variability of solar transmission and radiant heating rate in
the coastal ocean: optical impacts,” Chang, C. and T.
Dickey, IUGG
“History and Current Plans for U.S. Scientific Cabled
Observatories for Time Series,” Glenn, T. Dickey, and O.
Schofield, Scientific Submarine Cable 2003 Workshop
“The evolution of the Northeast Observing System for the
United States,” Glenn, S., O. Schofield, and T. Dickey,
IUGG
Nice, France
18
Miami
Honolulu, Hawaii
Washington, DC
Bologna, Italy
Miami
Villefranche, France
Washington, DC
New Orleans, Louisiana
New Orleans, Louisiana
Villefranche, France
Villefranche, France
Sapporo, Japan
Tokyo, Japan
Sapporo, Japan
Jul./2003
Sep./2003
Jan./2004
Jan./2004
Feb./2004
Feb./2004
Feb./2004
Feb./2004
Feb./2004
Feb./2004
Feb./2005
Mar./2004
Apr./2004
Jun./2004
Aug./2004
Sep./2004
Sep./2004
Oct./2004
Dec./2004
“Toward sampling biological and chemical variables over
relevant time-space scales: new sensor and platform
capabilities,” Invited Lecture for Next Generation of In Situ
Biological and Chemical Sensors in the Ocean
“Review of carbon and interdisciplinary measurements for
the Global Ocean Observing System,” Steering Committee
Meeting of the Coastal Ocean Observing System (Global
Ocean Observing System)
“Recent and Future Technologies,” ORION (Invited)
Co-chair of session on global ocean observing systems
American Geophysical Union Ocean Sciences Meeting
“The Multi-disciplinary Ocean Sensors for Environmental
Analyses (MOSEAN) Program,” Dickey, T., A. Hanson, D.
Karl, C. Moore, G. Chang, D. Manov, and F. Spada,
AGU/ASLO
“A decade of high temporal resolution interdisciplinary
observations using the Bermuda Testbed Mooring,” Dickey,
T., AGU/ASLO (Invited)
“Optical characterization of phytoplankton blooms in the
Santa Barbara Channel,” Chang, G.C., E.E. McPhee-Shaw,
and T.D. Dickey, AGU/ASLO
“E-Flux: Physical Observation Plans,” Dickey. T. and OPL
“MOSEAN CHARM Review and Plans,” Dickey, T. and
OPL
“MOSEAN HALE-ALOHA Review and Plans,” Dickey, T.
and OPL
“Review of time series technologies,” DEOS/ORION
Planning Meeting, Dickey, T, DEOS/ORION Steering
Committee Meeting.
“Review of interdisciplinary mooring time series for
SCCOOS,” Dickey, T. , Southern California Coastal Ocean
Observing System Workshop
“Discussion of MFSTEP progress in 2003,” Dickey, T.,
Mediterranean Forecast System: Toward Environmental
Prediction
“The International Geosphere-Biosphere Program (IGBP)
and biogeochemical measurements as part of GOOS,”
Dickey, T., Ocean Observing Panel for Climate Steering
Committee Meeting
“Review of the MOSEAN program,” Dickey, T., National
Science Foundation
“Extreme and episodic events in the ocean: recent results and
future studies,” Dickey, T., Bi-annual Challenger Society
Meeting (Keynote Speaker)
“OceanSITES: Ocean Sustained Interdisciplinary Timeseries
Environmental observational System,” Dickey, T., Scientific
Committee on Ocean Research (SCOR)
“Bio-optical relationships in the Santa Barbara Channel:
implications for remote sensing,” Chang, G.C., T. Dickey, C.
Moore, A. Barnard, R. Zaneveld, A. Hanson, and P. Egli,
Ocean Optics XVII
“Biological-physical interactions affected by extreme and
episodic oceanic events,” Dickey, T., American Geophysical
Union (Invited)
19
Woods Hole, MA
Ottawa, Canada
San Juan, Puerto Rico
Portland, OR
Honolulu, HI
Honolulu, HI
Honolulu, HI
Honolulu, HI
Honolulu, HI
Honolulu, HI
Santa Fe, NM
Santa Barbara
Brest, France
Southampton, UK
Arlington, VA
Liverpool, UK
Venice, Italy
Fremantle, Australia
San Francisco
May/2005
“
Geneva, Switzerland
Towards autonomous biogeochemical
and bio-optical measurements,” Ocean Observing Panel for
Climate (Invited),
June/2005
Auust/2005
Sept./2005
Nov./2005
Feb./2006
Feb./2006
Feb./2006
Feb./2006
Feb./2006
Feb./2006
Feb./2006
Feb./2006
Feb./2006
Feb./2006
Feb./2006
Apr./2006
Apr. /2006
“
Plymouth, UK
Interactive modeling and observational approaches for
solving interdisciplinary problems,” Advances in Marine
Ecosystem Modelling Research (AMEMR) Symposium
(Invited),
“Physical observations during E-Flux III” E-Flux Workshop
(Invited)
The future growth and use of interdisciplinary ocean
observations
(Invited talk for WHOI’s 75th Anniversary)
Overview of Ocean Physics Laboratory plans for the Office
of Naval Research (ONR) Radiance and Dynamics in the
Ocean
(RaDyO) program
Physical and bio-optical observations of cyclones in the lee
of Hawaii during the E-Flux experiments, Dickey et al.
E-Flux: influences of cyclonic eddy activity on Planktonic
food web dynamics and carbon export in the lee of Hawaii,
C. Benitez-Nelson et al.
The SCCOOS shelf to shoreline observatory development
Santa Barbara Channel mooring: an ongoingtime series of
currents, thermal structure, and optical properties of the
water column over the
continental shelf, E.E. McPhee-Shaw et al.
Exploring the World Ocean: a new inquiry-based? tool for
teaching 21st century oceanography, S. Chamberlin and T.
Dickey
Physical and bio-opticalobservations of cyclone Noah (EFlux I) in the lee of Hawaii, V. Kuwahara et al.
Physical and bio-optical observations of cyclone Opal (EFlux III) in the lee of Hawaii, F. Nencioli et al.
Upper ocean response to Hurricane Fabian and Tropical
Storm Harvey near Bermuda, W. Black and T. Dickey
Long-term monitoring of primary nutrient
concentrations in the coastal environment, P. Egli et al
Advection of detrital carbonate sediment to the deep ocean
by passage of Hurricane Fabian over Bermuda, J. Weber et
al.
Review of emerging technologies for OceanSITES
The HALE-ALOHA mooring program: toward cable
connection
“Overview of Ocean Physics Laboratory plans for the Office
of Naval Research (ONR) Radiance and Dynamics in the
Ocean (RaDyO) program,” T. Dickey and G. Chang
“Review of the Bermuda Testbed Mooring, HALE-ALOHA
Mooring and ORION Programs,” Eulerian Observation
Workshop, T. Dickey and O. Schofield (Invited)
20
Santa Barbara, CA
Woods Hole, MA
Narragansett, RI
Honolulu, HI
Honolulu
Honolulu, HI
Honolulu, HI
Honolulu, HI
Honolulu, HI
Honolulu, HI
Honolulu, HI
Honolulu, HI
Honolulu, HI
Honolulu, HI
La Jolla, CA
Monaco
May/2006
May 2006
Aug./2006
Sept./2006
Sept./2006
Oct./2006
Oct./2006
Jan./2007
Spring 2007
“Interdisciplinary Time Series Observational Systems,”
Ocean Observing Panel for Climate meeting, T.Dickey
(Invited)
“New Opportunities to observe and predict episodic and
extreme events in the ocean
,” T. Dickey and O. Schofield AGU (Invited Fellows Talk)
“Overview of MOSEAN program,” T. Dickey et al.
“The Bermuda Testbed Mooring and HALE-ALOHA
Mooring Programs: Innovative Deep-Sea Global
Observatories,”T. Dickey, G. Chang, O. Schofield, S. Glenn,
D. Karl, D. Peters, J. Kemp, C. Moore, A. Hanson, D.
Manov, and F. Spada (Invited)
“Physical and bio-optical measurements during the E-Flux
program,”F. Nencioli, V. Kuwahara, and T. Dickey (2
presentations)
“The Radiance in a Dynamic Ocean (RaDyO) program,”
T. Dickey, G. Chang, S. Ackleson,
M. Banner, T. Drake, T. Elfouhaily,
D. Farmer, J. Gemmrich, G. Kattawar, L. Lenain, M.
Lewis, Y. Liu, S. McLean, K. Melville, R. Morison, S.
Pegau, H. Schultz, L. Shen, D. Stramski, M. Twardowski,
S. Vagle, L. Vincent, K. Voss, H. Wijesekera, D. Yue, R.
Zaneveld, and C. Zappa
“Optical closure in a coastal environment,” G. Chang, A.
Whitmire, A. Barnard, J.R.V. Zaneveld, T. Dickey, and C.
Moore
“Interdisciplinary Oceanography: Recent advances using
moored-buoy platforms,” V. Kuwahara and T. Dickey
“Innovations in ocean optics for coastal and open ocean
mooring applications,” V. Kuwahara, G. Chang Spada, and
T. Dickey
Tokyo
Baltimore
Kona, Hawaii
Boston
San Diego
Montreal
Montreal
Tokyo
Aberdeen, Scotland
Field Activities: Over 132 research cruises have been conducted in study areas including the North Pacific
Ocean, North Atlantic Ocean, Mediterranean Sea, Equatorial Pacific Ocean, and Arabian Sea.
At-Sea Research Activities (M=Mooring/S=Shipboard/A=Autonomous Underwater Vehicles)
S-R/V Gilliss, 1977, Sargasso Sea CTD and SOFAR float deployment
S-R/V Researcher, 1978, Fine structure observations in the Bahamas
S-R/V New Horizon, 1981, Eddy in the California Current
S-R/P FLIP, 1982, Optical Dynamics Experiment, off San Diego
S-R/P FLIP, 1982, Optical Dynamics Experiment, Central North Pacific
S-R/V Columbus Iselin, 1985, Biowatt I, Sargasso Sea
M-R/V Knorr, 1985, Biowatt I, Sargasso Sea
S-R/V Seawatch, 1985, Los Angeles Outfall Study
S-R/V Seawatch, 1986, Los Angeles Outfall Study
S-R/V Seawatch, 1986, Biowatt II, Sargasso Sea
M-R/V Oceanus, 1987, Biowatt II, Sargasso Sea
M-R/V Atlantis II, 1989, MLML-Off coast of Iceland
M-R/V Endeavor, 1989, MLML-Off coast of Iceland
M-R/V Ewing, 1990, MLML-Off coast of Iceland
M-R/V Endeavor, 1991, MLML-Off coast of Iceland
M-R/V Seawatch, 1991, Los Angeles Outfall Study
21
M-R/V Oceanus, 1991, MLML-Off coast of Iceland (2 cruises)
M-R/V Malcolm Baldridge, 1991, Equatorial Pacific
M-R/V Discoverer, 1991, Equatorial Pacific
M-R/V Seawatch, 1992, Los Angeles Outfall Study (4 cruises)
M-R/V Malcolm Baldridge, 1992, Equatorial Pacific
M-R/V Discoverer, 1992, Equatorial Pacific
M-R/V Discoverer, 1993, Equatorial Pacific
M,S-R/V Seawatch, 1993, Bottom boundary layer off Los Angeles (2 cruises)
M-R/V Tethys II, 1993, Mediterranean Sea Flux Study
M-R/V Thompson, 1994, ONR Arabian Sea Study
S-R/V Kila, 1994, Honolulu, Hawaii Outfall Study
M-R/V Thompson, 1994, ONR Arabian Sea Study
M-R/V Weatherbird II, 1994, NSF/NASA Bermuda Testbed Mooring (2 cruises)
M-R/V Weatherbird II , 1995, NSF/NASA Bermuda Testbed Mooring (5 cruises)
M-R/V Thompson, 1995, ONR Arabian Sea Study
M-R/V Edwin Link, 1996, NSF/NASA Bermuda Testbed Mooring
M-R/V Weatherbird II, 1996, NSF/NASA Bermuda Testbed Mooring (3 cruises)
M-R/V Lamer, 1996, ONR CMO/Santa Barbara Channel test cruise
M-R/V Oceanus, 1996, ONR CMO/Martha's Vineyard (2 cruises)
M-R/V Oceanus, 1997, ONR CMO/Martha's Vineyard (3 cruises)
M-R/V Weatherbird II, 1997, NSF/NASA/ONR Bermuda Testbed Mooring (6 cruises)
M-R/V Knorr, 1997, ONR CMO/Martha’s Vineyard (2 cruises)
A-R/V Lucky Lady, 1998, LOOPS/Mass Bay
A-R/V Oceanus, 1998, LOOPS/Mass Bay
M-R/V Weatherbird II, 1998, NSF/NASA/ONR Bermuda Testbed Mooring (2 cruises)
M-R/V Weatherbird II, 1999, NSF/NASA/ONR Bermuda Testbed Mooring (6 cruises)
M-R/V Ron Brown, 1999, NOPP/O-SCOPE Ocean Weather Station 'P' in Pacific Ocean (1 cruise)
M-R/V Endeavor, 2000, ONR HyCODE/LEO-15 site N.J. coast (3 cruises)
M-R/V Weatherbird II, 2000, NSF/NASA/ONR Bermuda Testbed Mooring (3 cruises)
M-R/V Endeavor, 2000, ONR, HyCODE, LEO-15 site, New Jersey (3 cruises)
M-R/V Ka’imikai-O-Kanaloa (UH), 2000, NSF, Hawaii Ocean Time Series Mooring, Hawaii
M-R/V Weatherbird II, 2001, NSF/ONR, Bermuda Testbed Mooring, Bermuda (3 cruises)
M-R/V Endeavor, 2001, ONR, HyCODE, LEO-15 site, New Jersey (2 cruises)
M-R/V Mirai, 2001, WHOI, HiLaTS, North Pacific, off Japan
M-R/V Weatherbird II, 2002, NSF/ONR, Bermuda Testbed Mooring, Bermuda (2 cruises)
M-R/V Mirai, 2002, WHOI, HiLaTS, North Pacific, off Japan
M-R/V Weatherbird II, 2003, NSF/ONR, Bermuda Testbed Mooring, Bermuda (3 cruises)
M-R/V Sproul, 2003, NOPP MOSEAN CHARM mooring, Santa Barbara Channel
M-R/V Sproul, 2004, NOPP MOSEAN CHARM mooring, Santa Barbara Channel (2 cruises)
M-R/V Point Sur, 2004, NOPP MOSEAN CHARM mooring, Santa Barbara Channel (1 cruise)
M-R/V Weatherbird II, 2004, NSF/ONR, Bermuda Testbed Mooring, Bermuda (5 cruises)
M-R/V Ka’imikai-O-Kanaloa (UH), 2004, MOSEAN HALE-ALOHA Mooring, Hawaii (3 cruises)
S-R/V Ka’imikai-O-Kanaloa (UH), 2004, NSF Hawaii Eddy Experiment, Hawaii (2004)
S-R/V Wecoma (OSU) 2005, NSF Hawaii Eddy Experiment, Hawaii (2005) (2 cruises)
M-R/V Sproul, 2005, NOPP MOSEAN CHARM mooring, Santa Barbara Channel
S-R/V Wecoma (OSU) 2005, MOSEAN HALE-ALOHA Mooring, Hawaii (2 cruises)
S-R/V Kilo Moana (UH) 2005, MOSEAN HALE-ALOHA Mooring, Hawaii (2 cruises)
M-R/V Weatherbird II, 2005, NSF/ONR, Bermuda Testbed Mooring, Bermuda (4 cruises)
M-R/V Point Sur, 2005, NOPP MOSEAN CHARM mooring, Santa Barbara Channel (4 cruises)
M-R/V Point Sur, 2006, NOPP MOSEAN CHARM mooring, Santa Barbara Channel (3 cruises)
M-R/V RV Sproul, 2006, NOPP MOSEAN CHARM mooring, Santa Barbara Channel
S-R/V Kilo Moana (UH) 2006, MOSEAN HALE-ALOHA Mooring, Hawaii (5 cruises)
M-R/V Atlantic Explorer, 2006, NSF/ONR, Bermuda Testbed Mooring, Bermuda (2 cruises)
S-R/V Kilo Moana (UH) 2007, MOSEAN HALE-ALOHA Mooring, Hawaii
22
Contracts and Grants [Note: Approximately $20 million have been received in contracts and grants since
1979, with about $14 million of the total received since 1996]
1979-1996:
T. Dickey, A numerical model to assess the dilution and mixing of formation water discharged into the
marine environment, Minerals Management Service, July 1979 - December 1979, $12,000.
T. Dickey, A numerical model of the bottom boundary layer and sediment transport on the continental
shelf, National Science Foundation, July 1980 -December 1981, $27,000.
T. Dickey, D. Hammond, and J. Kremer, Gas exchange rates at the air-sea interface in coastal waters,
National Oceanic and Atmospheric Administration, October 1980 - September 1982, $86,000.
B. Jones and T. Dickey, Physical and chemical oceanography associated with an outfall, Los Angeles
County, 1983 – 1984, $13,000.
T. Dickey, Analysis and modeling of data taken during the Optical Dynamics Experiment, Office of Naval
Research, 1983 – 1984, $101,000.
T. Dickey and A. Bratkovich, A study of optical and physical variability in the open ocean, Office of Naval
Research, 1984 – 1986, $380,000.
B. Jones, A. Bratkovich, and T. Dickey, Physical and chemical oceanographic variability in the region near
the Los Angeles County White's Point outfall, National Oceanic and Atmospheric Administration, 1984
– 1986, $130,000.
T. Dickey and B. Pipkin, Oceanographic teaching, IBM grant for innovative teaching using computers,
1984 – 1985, $25,000.
T. Dickey and A. Bratkovich, Physical and bio-optical oceanographic measurements at Scripps Canyon,
Office of Naval Research, Oct. 1985 - Sept.1986, $55,000.
T. Dickey, Instrumentation for the Biowatt physical and bio-optical mooring experiments, DoD University
Research Initiative Program, July 1986 - June1987, $205,000.
T. Dickey and L. Washburn, Optical and physical variability in the open ocean, Office of Naval Research,
January 1987 - December 1988, $163,000.
T. Dickey, An acceleration for: Observations and modeling for the Biowatt program, Office of Naval
Research, May 1988 - September 1988, $35,000.
T. Dickey, Observations and modeling for the Biowatt program, Office of Naval Research, Oct. 1986 Sept. 1989, $650,000.
T. Dickey (with T. Granata), Laboratory studies of turbulence and marine aggregates, Office of Naval
Research (under subcontract from UC Santa Barbara), June 1988 - December 1990, $17,000.
T. Dickey, Development and testing of a longwave radiation sensor for deployment from ships and buoys
(in conjunction with the NSF sponsored World Ocean Circulation Experiment, WOCE), National
Science Foundation, October 1987 - September 1990, $489,000.
T. Dickey, An acceleration for: Observations and modeling for the Biowatt program, Office of Naval
Research, October 1988 – September 1990, $240,000.
T. Dickey, An enhancement to contract no. N00014-89-J-1498: "An acceleration for 'Observations and
modeling for the Biowatt program", ONR, July 1990 - December 1990, $50,173.
T. Dickey, Observations and modeling for the Marine Light in the Mixed Layer (MLML) program, Office
of Naval Research, October 1990 - September 1993, $280,000.
T. Dickey, High resolution biogeochemical and physical time series measurements in the equatorial Pacific
Ocean, NOAA Climate and Global Change Program, January 1991 - December 1992, $280,000.
T. Dickey, High resolution biogeochemical and physical time series measurements as part of JGOFS, NSF,
June 1991 - December 1992, $100,000.
T. Dickey, Temporal evolution of particulate distribution in the vicinity of an ocean outfall as forced by
physical and biological processes, NOAA, October 1990 - September 1993, $128,495.
T. Dickey, Biological response associated with mesoscale hydrodynamical structures in the western
Mediterranean: Instrumentation development and planning for a major field experiment, NSF, May
1992 - April 1994, $13,350 [A French companion proposal by Dr. Isabelle Taupier-Letage of
IFREMER was funded and the work was done in collaboration].
23
B. Jones and T. Dickey, The bottom boundary layer and sediment re-exposure on the Palos Verdes
continental shelf, NOAA, April 1992 - August 1994, $330,177.
T. Dickey, An incremental increase for the project: High resolution biogeochemical and physical time
series measurements in the equatorial Pacific Ocean, NOAA climate and Global Change Program,
February 1993 - January 1994, $69,516.
T. Dickey, Development of a testbed mooring program for interdisciplinary measurement systems, NSF,
July 1993 - June 1996, $200,000.
T. Dickey, J.A. Domaradzki, and R. Zaneveld, Light scattering induced by turbulent flow- a numerical
model, Office of Naval Research, Oct. 1993 - Sept. 1995, $65,000.
B. Jones, and T. Dickey, Plume initial dilution and dispersion in Mamala Bay, Hawaii, Mamala Bay Study
Commission, Apr. 1994 - Sept. 1995, $310,000.
T. Dickey, A model of coupled biological and physical processes in the equatorial Pacific during the 19911992 ENSO event, NASA, Sept. 1993-Aug. 1996, $66,000.
T. Dickey, Optical measurements from moorings in support of SeaWiFS, NASA, April 1994 - March 1997,
$480,000.
More Recent Grants and Contracts
Years
Source and Title
94-98
ONR, High resolution
time series observations
of bio-optical/physical
variability in the
Arabian Sea
95-00
ONR, Moored time
series measurements of
the vertical structure of
optical properties in the
coastal ocean
95-98
ONR, AASERT
96-97
ONR, DURIP
96-97
NSF, A testbed mooring
program for interdisc.
studies
96-98
ONR, AASERT
97
UCSB,
Instructional
improvement grant
97-98
NASA, Center of
Excellence
97-00
NASA, SIMBIOS
97-98
NOPP, ONR, Littoral
Ocean Observing
System (LOOPS)
97-98
NASA, Optical
measurements from
moorings in support of
SeaWiFS
98-01
NOPP, ONR,
Oceanographic-Systems
for Chemical, Optical,
and Physical
Experiments
98-01
ONR, AASERT
98-01
NSF, Bermuda Testbed
Mooring
24
Amount
$1,010,000
P.I. Status
PI
$527,000
PI
$86,965
$219,945
$535,642
PI
Co-PI
PI
$31,000
$7,985
PI
Co-PI
$395,480
Co-PI
$519,574
$180,000
PI
PI
$150,000
PI
$1,991,616
Lead-PI
$168,940
$720,462
PI
PI
99-00
99-01
99-01
99-03
00-01
00-01
01-03
01-03
01-06
02-02
02-07
03-04
03-06
04-05
05-10
YSI, Tethered buoy
system
NSF, Bermuda Testbed
Mooring (BTM): A
community resource
ONR, High resolution
time series
measurements
(HyCODE)
ONR High resolution
time series
measurements
(HyCODE)
NSF, Next generation
surface buoy
ONR, DURIP HyCODE
equipment
UC-MEXUS Suspended
sediment concent. and
fluxes on tidal flats in
the upper Gulf of
California
NOPP, ONR
Oceanographic-Systems
for Chemical, Optical,
and Physical
Experiments
NSF Bermuda Testbed
Mooring
WHOI HiLaTS (Japan)
NOPP Multidisciplinary Ocean
Sensors for
Environmental Analyses
and Networks
2nd Institute
Oceanography, China,
Development of DeepSea Sensors
Influence of Cyclonic
Eddy Activity on
Planktonic Foodweb
Dynamics and Carbon
Export in the Lee of
Hawaii
NOAA, SCCOOS: Shelf
to Shoreline
Observatory
Development
ONR, RaDyO
25
$64,920
PI
$181,421
PI
$749,649
PI
$1,028,410
Lead-PI
$63,847
PI
$161,731
PI
$2,500
PI
$149,621
PI
$2,250,000
Lead-PI
$75,000
$2,500,000
PI
Lead-PI
$14, 749
PI
$248,967
PI
$138,770
Co-PI
$967,349
Lead-PI with Grace
Chang
Selected Recognitions and Committee Memberships:
Fellow of the American Geophysical Union
Editor for Reviews of Geophysics
Guest Editor for Journal of Geophysical Research Special Volume
Editorial Board for the Journal of Marine Systems
Associate Editor for Limnology and Oceanography Methods
Guest Co-editor for Limnology and Oceanography Special Volume: Scientific Results from Autonomous
and Lagrangian Platforms and Sensors
Co-author of Journal of Geophysical Research paper, “Coastal ocean optical influences on solar
tranmission and radiant heating rate,” by G. Chang and T. Dickey, which was selected as an AGU
Journal Highlight Article in 2004.
Co-author of Journal of Geophysical Research paper, “Satellite evidence of hurricane-induced plankton
blooms in the ocean desert,” by S. Babin, J.A., Carton, T.D. Dickey, and J.D. Wiggert, which received
the Johns Hopkins Applied Physics Laboratory’s award for Outstanding Research Paper in the
Externally Refereed Publication in 2005.
Co-author of paper for which Dennis McGillicuddy received ASLO Lindeman Award 2000
Co-Lead-PI for ONR Radiance in a Dynamic Ocean (RaDyO) Program
Lead-PI for NOPP MOSEAN (Multi-disciplinary Ocean Sensors for Environmental Analyses and
Networks) program
Lead-PI for NOPP O-SCOPE (Ocean-Systems for Chemical, Optical, and Physical Experiments) program
Lead-PI for Bermuda Testbed Mooring program
Lead-PI for ONR HyCODE (Hyperspectral Ocean Dynamics Experiment) program
Chair of Review Committee: Southampton Oceanographic Centre (George Deacon Division), UK
Member of the CORE Steering Committee on Research at Ocean Observatories Program
Member of the Advisory Committee for the NOPP Gulf of Maine Ocean Observing System
Member of Meetings Committee for The Oceanography Society
External Advisory Board for the University of Massachusetts Center for Marine Science and Technology
Co-chair of National Academy of Sciences (NAS) workshop “Towards a National Collaboratory”
Member of the NSF Ocean Research Interactive Observatory Network (ORION) program Science and
Technology Committee
Member of two National Research Council, National Academy of Sciences review panels
Executive Committee for NOPP Littoral Ocean Observing and Predictive System (LOOPS)
Councilor (elected office 2 times; 1992; 2007) for The Oceanography Society (TOS), Chair of Annual TOS
Meeting 1991
Steering committee member for ONR Biowatt and Marine Light in the Mixed Layer Experiments
Member ad hoc Global Ocean Observing System (GOOS) Living Marine Resources Working Group
Member U.S. JGOFS Steering Committee, Chair of Time-series Oversight Committee and Chair of
Workshop on Bio-optics in JGOFS
Member U.S. GLOBEC Steering Committee, Chair of Technology Committee
Member International GLOBEC Steering Committee, Chair Sampling and Observations Committee
Member of International Convention of the North Pacific Marine Science Organization (PICES) Working
Group 2 on Development of Common Assessment Methodology for Marine Pollution
Member of Santa Barbara Maritime Museum Exhibit Committee
Invited lecturer for the NATO Advanced Study Institute Summer School on The Ocean Carbon Cycle and
Climate (Ankara, Turkey, August 2002)
Co-chair of the International Workshop on Autonomous Measurements of Biogeochemical Parameters in
the Ocean (Honolulu, Hawaii, 2001)
Co-chair of Southern California Bight Ocean Observing and Modeling System Workshop (Santa Barbara,
2001)
Co-chair of the Scientific Cabled Observatories for Time Series (SCOTS) Committee under NSF
Member of Steering Committee for Dynamics of Earth and Ocean Systems (DEOS) (under NSF)
Member of the Steering Committee and Invited Speaker for the Workshop on Real-Time Systems for
Observing Coastal Ecosystem Dynamics and Harmful Algal Blooms (HABWATCH) (Villefranche,
France, June, 2003)
Advisory Committee for the Mediterranean Forecast System: Toward Environmental Predictions
26
Member of the International Ocean Observing Panel for Climate (OOPC) Committee under the Global
Ocean Observing System (GOOS)
Member of the Time Series Science Team for the Development of Global Eulerian Observatories (GEO)
[now called OceanSITES] (under OOPC and GOOS)
Member of the Steering Committee for the Sargasso Sea Ocean Observatory (S2O2)
Sigma Xi Science Honorary
Sigma Pi Sigma Physics Honorary
Introduction and Overview
I completed undergraduate degrees in physics and mathematics in 1968 at Ohio University. During my
ensuing service in the U.S. Coast Guard, I was fortunate to have had the opportunity to teach electronics
(and briefly human relations) and to complete an M.S. degree in physics through evening classes at Stevens
Institute of Technology. Toward the end of my service period, I also taught math and physics at the
introductory college level (New York Institute of Technology) in the evening. I found teaching to be most
rewarding and importantly was introduced to the subject of oceanography by fellow Coast Guardsmen who
were studying to be marine technicians. I borrowed the classic book, The Oceans, by Sverdrup, Johnson,
and Fleming along with books on meteorology and ecology from some of these students. After reading
these, I decided to pursue a teaching and research career focusing on environmental problems.
Following completion of my four years of Coast Guard service, I entered the Princeton University
Geophysical Fluid Dynamics Program, which was an ideal environment for me as it was physics-based, it
placed a heavy emphasis on self-study, and the professors, scientists, and fellow students were
exceptionally stimulating. General circulation models of the atmosphere and ocean were being developed
for climate studies on the large scale in the same setting where fundamental breakthroughs were being
made in equatorial dynamics, weather prediction, and turbulence closure modeling. My Ph.D. thesis
(completed under Professor George Mellor) concerned the fundamental problem of transition between
turbulence and internal waves, but I also did a class project concerning equatorial waves (under Professor
George Philander), resulting in my first Journal of Geophysical Research paper.
Upon completion of my Ph.D. at Princeton (1977), I received a competitive Rosenstiel Fellowship from
the University of Miami to do research in any area of my choice. I decided to pursue interdisciplinary
studies involving physical and biological interactions at a time when disciplinary oceanography was the
norm and interdisciplinary research was still not encouraged. Despite this, I followed a career path in
interdisciplinary studies. My first interest concerned the interaction of physical and biological processes,
particularly through the application of mixed layer models to biological problems. It became evident that
interdisciplinary models would require biological data on scales comparable to physical data. At that time,
few biological and optical instruments with adequate sampling capabilities were available. However, in the
course of the next few years, several advances were made in a new field of study, bio-optics, which has
changed the direction of biological and optical oceanography and has clearly influenced much of my
research. I am currently writing a book on bio-optical oceanography and its applications.
Following a year at the University of Miami, I accepted an Assistant Professor position at the University
of Southern California (USC). USC had recently hired biological and geochemical oceanographers, who
were anxious to interact with a physical oceanographer. Being the lone physical oceanography professor at
USC and having keen interests in interdisciplinary studies, I formed close relationships with biological and
geological oceanographers and began to work in the areas of marine biology, optics, and geology. Over the
years, I have been able to attract some excellent students and research associates to my group (described in
vita). Most developed interdisciplinary interests and expertise. Several have become leading practitioners
and proponents of interdisciplinary oceanographic research. My 18 years of research at USC were
exceptionally diverse and, of course, highly interdisciplinary. Thus, my research funding has been derived
from almost all possible agencies in physical, biological, optical, geological, and chemical oceanography
and ocean technology. I enjoy identifying important and societally relevant scientific problems, writing
papers and books, directing graduate student research, and finally sharing my research discoveries and
experiences with large numbers of undergraduates, graduate students, and colleagues on the international
level.
Teaching has been one of my favorite activities, but I have also been involved in and often led major
interdisciplinary national and international programs and have developed an international network of
collaborators; this has been especially rewarding for my students as well as myself. I feel that one of my
27
more important attributes is my ability to help bring the best out of students and colleagues, whether
serving as a leader or as a participant. I have encouraged students to pursue research areas that they prefer,
sometimes leading to work with and direction by other faculty members. I feel that this flexibility has been
advantageous for the students as well as our group as "disciplinary and idea boundaries" simply do not exist
for us.
The accomplishments described in my vita and this personal statement clearly represents our group's
(Ocean Physics Group, OPG, at USC, and Ocean Physics Laboratory, OPL, at UCSB) team efforts, which
have often been enabled or enhanced by our many collaborators. During my career, I have attempted to
give credit to, and help to advance the careers of, my students and other members of our group as well as
our colleagues. Thus, there are often many co-authors on our papers, frequently with first authorship by
students, post-doctoral fellows, research associates, and engineers. I am proud that many of the past and
present members of the OPG and OPL continue to work on projects and write papers together and with my
present group as well as to network with each other to identify research and career opportunities.
My appointment to the faculty of UCSB began a bit more than 8 years in January 1996. Since much of
our group’s activity is observational and based upon instrumentation and new technologies, the first year at
UCSB required our group to accomplish several logistical tasks including finding off-campus space,
moving instrumentation, office materials, etc. from USC to UCSB, purchasing new laboratory equipment,
office furniture, and computers, setting up telephone and computer communication links, and transferring
grants and contracts. At the same time, we were conducting two major field programs, the Bermuda
Testbed Mooring (BTM) program (I am lead-PI) and the Coastal Mixing and Optics (CMO) program (I
was co-editor of Journal of Geophysical Research Special Volume for CMO). Our group responded to the
challenges of the move, adapting to a different administrative structure, and maintaining continuity of our
field intensive research programs.
During the past few years, our research has focused on development of new technologies, observationally
based research, and modeling. Our group is well known for developing innovative interdisciplinary
instrumentation that allows observations on time scales from a few minutes to several years. Much of our
work focuses on interactions among physical, bio-optical, and biogeochemical processes. Our research
spans both coastal and open ocean waters and often contributes to the advancement of remote sensing of
the oceans. We have led three major technological development programs recently: Office of Naval
Research (ONR) National Ocean Partnership Program (NOPP) Ocean-Systems for Chemical, Optical, and
Physical Experiments (O-SCOPE with sites at Ocean Station P in the North Pacific, Bermuda, and off
Monterey, California), NSF/ONR/NASA Bermuda Testbed Mooring (BTM) program, and NOPP NSF
Multi-disciplinary Ocean Sensors for Ecosystem Analyses and Networks (MOSEAN) program (sites off
Hawaii and Santa Barbara). I have been a major proponent of the philosophy of the NOPP style of
projects, which encourages collaborations among academic and research institutions, government
laboratories, and the private sector. The BTM program is also a research program. We have also led the
ONR Hyperspectral Coastal Ocean Dynamics Experiment (HyCODE) research program (sites in Bahamas,
West Florida Shelf and off New Jersey). Other research programs that we play major roles in include High
Latitude Time Series (HiLaTS, using three moorings in the North Pacific off Japan) with U.S. and Japanese
collaborators and a project in the Gulf of California with Mexican and UK collaborators. NSF has funded
us recently with collaborators for a new study of eddies off the Hawaiian Islands. Our research over the
past three years has been conducted in the North Pacific off Canada and off Japan, in the North Atlantic,
and off the east and west coasts of the U.S. Our research is leading to better understanding of episodic and
extreme events such as internal solitary waves, hurricanes, and mesoscale eddies. These phenomena have
been vastly undersampled previously, and thus their importance and contributions to oceanic variability
have remained as major enigmas for our science. Nonetheless, our cutting-edge technologies and analyses
are proving critical in solving these problems. We are actively promoting the use of data assimilation
modeling and remote sensing to complement in situ observations in order to address problems that
encompass time and space scales spanning over ten orders of magnitude.
While much of our observational activity has focused on interdisciplinary moorings around the world, we
have made strides in new sampling technologies involving autonomous underwater vehicles (AUVs) with
successful collaborative studies using two different AUVs (Autosub (Southampton Oceanographic Centre,
UK)) and (Odyssey (MIT)) during experiments near the BTM site and in Massachusetts Bay, respectively.
Our research and technological developments have become increasingly important internationally as
evidenced by the various activities described in my vita. In particular, we have developed interactions
28
and/or collaborations with oceanographers in several countries including the United Kingdom, France,
Japan, Taiwan, China, Turkey, New Zealand, Germany, and Italy. The impact of our research is reflected
in the number and significance of our publications. In addition, it is worth noting that the ideas and thrust
of our research and technological endeavors, which were previously considered rather radical and often
challenged, are being adopted by many and appear to be approaching mainstream.
Education
I feel that I have an enthusiastic and motivational teaching style. Most students seem to relate easily to
me, perhaps because I really enjoy and value them. I attempt to excite students about the ocean and the
environment, emphasizing 1) the uniqueness and importance of the ocean, 2) the relevance of
oceanography to climate change and society in general, 3) implications of pollution using real world
examples from our work off the California, Hawaiian, and Massachusetts coasts, and 4) that everyone can
make a difference through personal actions and through involvement with various environmental
organizations. One reason that I feel that my efforts are so important is that I have had the opportunity to
educate such a large number of students, many of whom have made and will be making key environmental
decisions.
Both undergraduate and graduate education are important components of my teaching and advising
activities. The two are highly complementary with our research programs, which provide opportunities for
direct involvement with cutting edge scientific studies, several in diverse geographic regions (e.g., Arabian
Sea, Bermuda, Mediterranean Sea, equatorial Pacific, east and west coasts of the U.S., and others). The
classroom experience is also greatly enhanced by our field activities. I have taught one of the major entrylevel courses (Oceans and Atmospheres) throughout my career (typically 250-350 students per class).
Several students have indicated that they selected Geography or Environmental Studies majors based on
my courses. Other new courses have also been developed.
The graduate education aspect has also proven successful with the production of some excellent graduate
students. In summary, I am proud of the quality and quantity of the students I have taught during my
career. The statistics show that I have now taught over 5,000 undergraduates, and served on over 100
graduate committees; nineteen graduate (M.S. and Ph.D.) degrees have been completed under my
supervision. Eleven advanced research scientists have done research in our laboratory. In addition, I have
directed several undergraduate research projects. It is worth noting that the professional staff of our group
(e.g., engineers, post-doctoral fellows) works very closely with our students so that they are well trained in
all aspects of field oceanography (our group has participated in 100 research cruises. Finally, I am in the
process of writing two books, one as sole author (Bio-optical Oceanography and Its Applications, Elsevier;
text is 2/3 completed) and the other an introductory textbook with a co-author, Sean Chamberlin (Exploring
the World Ocean, McGraw-Hill; also text is 2/3 completed). I am an inveterate writer and want to reach as
many individuals as possible in order to attempt to educate them about the ocean and the earth sciences.
Summary of Research
Overview
Our research is directed toward interdisciplinary oceanographic and environmental problems including:
upper ocean dynamics, bio-optics, ecology, biogeochemistry and global climate change (greenhouse
effect), coastal water pollution, bottom boundary layers, and sediment resuspension. Recent efforts have
emphasized studies of physical/biological processes and interactions on time scales from minutes to the
interannual, yet some of our work retains focus on fundamental physics at the air-sea interface and in the
upper and bottom layers of the ocean. Our group is studying both open and coastal ocean domains
simultaneously. We continue to expand both disciplinary and interdisciplinary efforts toward multiplatform (in situ and remote sensing) observational networks for science, monitoring, and modeling with
application to coastal pollution and global climate change. Our work often involves innovative
development and use of new technologies. An important aspect of our work has concerned the
development of instrumentation and techniques for linking in situ and remote sensing observations,
particularly through use of mooring-based measurements for groundtruthing (calibration/validation) ocean
color satellite sensors. Our optical systems are also proving useful for attacking fundamental problems such
as optical closure (i.e., quantifying relationships between inherent and apparent optical properties (IOPs
and AOPs) and testing radiative transfer models). Our innovative sampling technologies and their optimal
utilization are especially important, as the oceans remain so sparsely sampled; new ocean discoveries
29
require novel direct observations. The instrumentation we deploy allows us to explore the physical, optical,
biological, geological, and chemical environment and complex couplings at unprecedented time scales
(minutes to years) allowing us to discover new processes and to quantify and model these processes. Our
work is changing the way scientists are thinking in terms of the importance of episodic and high frequency
phenomena. These were previously under- or unsampled and thus generally assumed unimportant. This is
clearly not the case according to our results. New paradigms are being generated because of our
measurements, analyses, and modeling studies (examples are presented in our publications). Although
much of our work is observational in nature, we also utilize (and contribute to) satellite remote sensing and
numerical modeling methods. Several students have done theses using our unique data sets in combination
with numerical models (e.g., most recently by students Grace Chang and Sarah Zedler). It is worth noting
that our data sets are made available quickly after collection and are being used by many investigators
worldwide to interpret their results and to develop complex physical (e.g., air-sea interaction for hurricanes
and monsoons) and interdisciplinary (e.g., biogeochemical and sediment resuspension) models. Data
telemetry and autonomous underwater vehicle (AUV) sampling methods are key technical thrusts along
with sensor and system development by our group. These aspects are becoming more valued as ocean
prediction is becoming more feasible.
The impact of our research is evident in several ways including high productivity in the refereed
literature, large and diverse extramural funding, extensive advisorial activity, and demand for our students
and expertise. Many of our experiments utilize a variety of observing platforms and our mooring results
are often essential for the proper interpretation of data collected from the other platforms. Thus, the impact
of our work is often multi-faceted, enabling, and multiplicative.
Some specific research areas are highlighted below:
1. Air-Sea Interaction, Upper Ocean Dynamics, Extreme and Episodic Events, Bio-optics, and
Biogeochemical Cycling:
My Ph.D. thesis concerned a fundamental problem of geophysical fluid dynamics: the transition between
internal gravity waves and turbulence. This work was used as the basis for our group’s laboratory studies
concerning the exchange of gas across the air-sea interface. These studies remain of considerable interest,
particularly because of the transport of carbon dioxide and other greenhouse gases across the air-sea
interface (greenhouse gases and their roles in the climate change problem). In addition, our laboratory
experiments were used in joint work with Alice Alldredge (UCSB) to study the effects of turbulence on the
strength of “marine snow” and the disaggregation of particles. Recently, a theory described in my Ph.D.
thesis has been utilized by my thesis advisor George Mellor (Princeton) for a reformulation of his
commonly used turbulence closure model. We have just used this model and three others to explore the
physical processes contributing to the dynamics and thermodynamics of the upper ocean in the wake of
Hurricane Felix. This work has additional importance in regard to hurricane dynamics and prediction (e.g.,
feedbacks, hurricane intensity, and trajectories of hurricanes). We have another Journal of Geophysical
Research paper in press with co-authors concerning the apparent increase in chlorophyll and primary
production in the wakes of several hurricanes.
Our field experiments in the early 1980’s utilized R/P FLIP as part of the Optical Dynamics Experiment
(ODEX) in the central North Pacific. Our theoretical and observational papers concerning air-sea
interaction and upper ocean thermodynamics, dynamics, and bio-optics contributed to an important
paradigm shift, namely “variability in biological productivity can significantly affect upper ocean thermal
structure, heat budgets, and currents.” Further, the potential use of bio-optical time series data for
estimating primary productivity was demonstrated. We also pursued the physical/atmospheric longwave
radiation problem (part of the World Ocean Circulation Experiment, WOCE) using theoretical, laboratory,
and field approaches to better characterize longwave (LW) determinations from buoys and ships. Our
results appear to have led to improved field determinations, satellite groundtruthing, and modeling of the
LW component of the heat budget.
Over the past two decades years, we have done several experiments utilizing moorings to obtain high
temporal resolution (minute-scale), long-term (2-months up to about 10 years) time series to study air-sea
interaction, thermodynamics, dynamics, bio-optics, biological productivity, biogeochemistry, and sediment
resuspension in diverse ocean regions including: the Arabian Sea, the North Atlantic Ocean off Bermuda
and off Iceland, off the east coast of the U.S., the Mediterranean Sea, the central equatorial Pacific, off
30
Hawaii, and off the west coast of the U.S. Processes ranging from the seasonal cycle down through
minute-scale cloud fluctuations have been studied for the first time in such detail through these collective
research efforts. Our data sets have shown that springtime mixed layer shoaling and phytoplankton blooms
can occur within only a few days and can effectively influence each other. This aspect alone represents a
major advance as modelers of seasonal productivity had been limited to only a few data sets collected at
monthly intervals previously (Menzel and Ryther, 1960, 1961), resulting in aliasing and undersampling.
Our group and others have used interdisciplinary physical-biological models to simulate the physical and
biological seasonal cycle.
Inertial motions and their effects have been studied theoretically and observationally. Within the past few
years we have collected extraordinary data sets as hurricanes have passed over our moorings off Bermuda
and south of Cape Cod, Massachusetts. These unique data sets (unobtainable from ships) have been, and
are still being, analyzed and modeled. The testing and development of models of the ocean’s response and
sediment resuspension in the wakes of hurricanes are enabling us to better understand the physics of these
highly episodic and energetic phenomena. This research has important implications for hurricane
prediction and their effects.
Mesoscale features including eddies and fronts have been studied by our group since the 1980’s and
continue to be of special interest in terms of biogeochemical cycling. The combination of trapped inertial
waves and mesoscale features was examined using our early Sargasso Sea data sets. We have reported the
first direct measurements of bio-optical and chemical time series as a major eddy passed the Bermuda
Testbed Mooring. These observations and their interpretation are especially important in balancing the
nutrient budget of the North Atlantic and explaining the role of the biological pump in carbon cycling in the
oligotrophic ocean. Our interdisciplinary time series data obtained in the Arabian Sea also indicated the
importance of mesoscale features, especially in terms of flux of organic carbon to the deep sea. In addition,
the monsoonal cycle was shown to be important for biogeochemical cycling and primary production in the
central Arabian Sea. Variability in the penetrative component of solar radiation was demonstrated to be
significant as well. From autumn of 2004 through spring of 2005, we will be conducting an intensive
physical-biogeochemical eddy experiment in the lee of the Hawaiian Islands with collaborators as part of
an NSF-funded project.
Another geographic area of central interest for interannual variability and global climate change is the
equatorial Pacific where we made the first high-resolution time series measurements of bio-optics and
physics concurrently. These data were used to compute time series of primary productivity. The primary
productivity was shown to be related to equatorial longwaves including tropical instability waves (TIWs)
and Kelvin waves. Interestingly, the TIW passages appear to act as natural iron enrichment events.
Further, both El Niño and “normal” phases were observed during the 18-month mooring observations, so
that we were also able to quantify primary productivity for these two extreme cases.
Although most of our biologically oriented research has focused on the lower trophic levels (e.g.,
phytoplankton), we have also devoted considerable effort toward research concerning higher trophic levels.
In particular, we have contributed to the ideas concerning predator-prey interactions, especially in regard to
the effects of turbulence. Some of my earliest committee work (Recruitment Experiment (REX II)
Workshop, 1978) involved this problem and population dynamics as they affect fisheries. This activity
preceded and contributed to the initiation of the major U.S. and international GLOBEC (Global Ocean
Ecosystem Dynamics) programs. I have continued my community service to these programs until the past
few years; I am now shifting more energy toward the Global Ocean Observation System (GOOS) initiatives
that include the full spectrum of interdisciplinary ocean observations.
2. Coastal Processes, Bottom Boundary Layers, and Pollution:
Some of my first work in the area of coastal oceanography, and in particular bottom boundary layers,
utilized a turbulence closure model and a data set collected off the coast of Peru. The results of the work
showed excellent agreement between the model and the data indicating one of the few clear examples of a
classic bottom Ekman layer. Later, I began work in coastal waters off the Palos Verdes Peninsula (near
Los Angeles) where an outfall was discharging about 300,000 gallons of treated sewage daily and where
over 100 tons of DDT are buried in sediments off the Palos Verdes Peninsula. The DDT problem has been
of special interest as it has been the subject of a multi-million dollar lawsuit and a controversial “capping”
experiment is underway. Importantly, our work has been of fundamental scientific value as we have studied
the problem of dispersion and mixing as well as sediment resuspension. By sampling very rapidly (minute-
31
scale) and continuously, we discovered a new process for sediment resuspension, an "ocean-bottom pump."
The process involves resonantly generated near-bottom, internal solitary waves (ISWs), which are not
presently included in models of sediment resuspension. More recent studies in the area by our group and
collaborators have entailed mapping of sediment resuspension areas off Palos Verdes. The Palos Verdes
studies along with our research off of Honolulu (Mamala Bay) have examined the fate of ocean outfall
waters (treated sewage) by using moorings, bottom tripods, and ship tow-yo surveys. Importantly,
advanced optical instrumentation has been utilized to allow us to better understand the fundamental
processes of dispersion and advection. Our work with AUVs in Massachusetts Bay (site of the Boston
municipal sewage outfall) represents a future approach for monitoring, modeling, and managing municipal
wastes through adaptive sampling and data assimilation.
The CMO experiment was devoted to a host of processes, which affect optical variability on the
continental shelf south of Cape Cod, MA. Our time series measurements of physical and bio-optical
variables have been used for examining physical/bio-optical interactions and sediment resuspension. The
passages of packets of internal solitary waves and two hurricanes (Edouard and Hortense) have provided us
the opportunity to analyze and model these processes and their effects on particles and their associated biooptical properties for the first time. In addition, the spectral data sets have been utilized to model the
partitioning of the various components of spectral absorption. Simulations of the bottom boundary layer
using a turbulence closure model have demonstrated that wave and mixing effects are important for
sediment resuspension during the hurricane passages.
3. Ocean Technology:
Ocean technology is of special importance because in situ interdisciplinary observations of the ocean are
so sparse in both time and space. My particular interest in ocean technology resulted from a desire to
develop interdisciplinary coupled models of the upper ocean. Our early modeling experiments utilized
varying optical water types and provided interesting insights, but few data were available for validation or
model development. As mentioned earlier, I realized that special in situ optical and biological data were
going to be required with sampling at time and space scales comparable to those of the physical variables.
The shipboard-profiling mode of sampling was being utilized by many investigators. However, I felt that
important breakthroughs would require concurrent physical and biological high-resolution long-term, time
series, which would be capable of capturing a nearly complete suite of processes. Clearly, inclusion of
important diel, internal gravity wave, inertial, sub-mesoscale, mesoscale, seasonal, and interannual scale
processes required such time series. During the Biowatt experiment in the North Atlantic, our group
modified an autonomous profiler (cyclesonde) and obtained a minimal set of physical and bio-optical data.
Next we developed a prototype multi-variable moored system (MVMS), which was based on a vector
measuring current meter (VMCM). We initially modified the VMCM by adding bio-optical and chemical
sensors (beam transmissometer, stimulated fluorometer, photosynthetically available radiation (PAR)
sensor, and dissolved oxygen sensor). MVMS’s have been used for several of the experiments described
earlier. More recently, we have developed several new optical systems to measure inherent and apparent
optical properties spectrally during the Bermuda Testbed Mooring (BTM) program, Coastal Mixing and
Optics program, and the HyCODE program and the NOPP O-SCOPE and MOSEAN programs.
The Bermuda Testbed Mooring (BTM) program, which has been sponsored by NSF, ONR, and NASA,
provides the oceanographic community with a deep-water platform for testing new instrumentation.
Scientific studies also utilize data collected from the BTM. Surface instruments have collected
meteorological and spectral radiometric data from the buoy tower and measurements at depth have
included: currents, temperature, and bio-optical, chemical, and acoustical variables. The BTM captures a
broad dynamic range of oceanic variability (minutes to years). During the BTM program, several new
sensors and systems have been tested by U.S. and international groups. These include new measurements
of pCO2, dissolved oxygen, nitrate, trace elements, several spectral inherent and apparent optical properties,
14C for primary production, and currents. Our NASA SIMBIOS study using the BTM demonstrated that
moorings-of-opportunity can be effectively used to collect very large volumes of accurate spectral
radiometric data. Already these data sets have been used to evaluate the performance of the SeaWiFS
ocean color satellite sensors. Several of the scientific results described earlier (Hurricane Felix and eddy
passages) and more recently data collected during the passage of Hurricane Fabian (September, 2003) were
made possible through the BTM program; also, a large number of investigators are using the program for
science and technology.
32
Our HyCODE project has focused on higher spectral resolution (nanometer scale resolution across the
visible spectrum) measurements, which we use to develop relationships between IOPs and AOPs and
ultimately to identify and quantify the various contributions to the optical signals (e.g., phytoplankton by
species groups, detrital materials, dissolved matter, etc.). These data sets are also important for validation
and algorithm development for the Navy hyperspectral imagers flown in aircraft. This work has entailed
cooperative efforts with specialized companies. A recent example of a highly collaborative, integrative
activity is the National Ocean Partnership Program (NOPP) Ocean-Systems for Chemical, Optical, and
Physical Experiments (O-SCOPE) project. Investigators came from universities, private research
institutions, government laboratories, and private industry. Important advances resulting from the OSCOPE work include the development of new mechanisms for reducing the adverse effects of biofouling,
new chemical sensor capabilities, and telemetry of data from remote sites. The ongoing NOPP MOSEAN
project (sites off Hawaii and Santa Barbara) builds on O-SCOPE and expands its objectives to develop
additional in situ chemical and hyperspectral optical sensors.
As mentioned earlier, we have worked with autonomous underwater vehicles (AUVs) in order to
complement our mooring time series activities. AUVs have great potential for providing spatial data sets.
Thus far, we have interfaced bio-optical sensors to the Southampton Oceanographic Centre’s (SOC)
Autosub AUV in collaboration with Gwyn Griffiths of SOC and examined spatial variability in the vicinity
of the BTM. In addition, we have studied fronts, sub-mesoscale features, and sediment resuspension using
the Odyssey AUV (in collaboration with Jim Bellingham, now at MBARI) in Massachusetts Bay.
I plan to continue my international efforts on behalf of interdisciplinary oceanography and earth sciences,
new ocean technologies, and global observing systems. I will contribute reviews in these areas as in the
past. Because of the sparseness of ocean data, we will also continue to work with collaborators in the
general areas of ocean sampling and observing systems (in situ and remote) and data assimilation
modeling.
33
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