Download Depths divided: Energy: Oxygen: Thermohaline Circulation

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

page
1
page
2
page
3
page
4
page
5
page
6
Document related concepts
no text concepts found
Transcript 
Lecture #16 (part 2)
Week #14
Depths divided:
y Mesopelagic: Immediately below epipelagic
y dim light (1%, no photosynthesis)
y ~ 200‐1000m
No light (0% light)
Oxygen:
y Oxygen exchange occurs @ surface
y Respiration & decomposition in deep
y Why not use up?
y How can oxygen‐rich water move deeper?
A.K. Morris, Ph.D.
y Energy in the deep sea:
y No PP
y Rely on carbon from above
o
(Except hydrothermal vents & cold seeps)
y Low abundance
y 5x fewer organisms at 500m
DEEP SEA
y Bathypelagic
y Abyssopelagic
Energy:
y 10x fewer at 4,000m
Thermohaline Circulation
y Ocean circulation driven by differences in H2O density, due to temp & salinity
y Cold, salty water sinks
y Great ocean conveyor: global circulation replenishes O2 to the deep
Lecture #16 (part 2)
Mesopelagic
Week #14
Shrimp and shrimp-like animals a-plenty
y ‘Midwater’ organisms (no structures, just like epipelagic)
y Diverse organisms
y Most w/ photophores (light organs)
y Squid, vampire squid, shrimp, lanternfish & bristlemouth
Oxygen Minimum Zone
y Despite Thermohaline
Circulation
y Just below photic zone, O2
minimum
y Diversity generally low right
here but increases just below
as O2 returns with depth Feeding (getting energy)
y Midwater depends on surface productivity
y 20% of surface PP sinks to mesopelagic
y Different strategies for saving E & getting E
y Mesopelagic fish are small
y Require less E
y Large mouths & extendible jaws
y Hallmark generalists!
A.K. Morris, Ph.D.
Midwater
Anglerfish
Lecture #16 (part 2)
Mesopelagic feeding strategies:
Vertical migrators
1.
y
2.
Zooplankton and fish
Stay in mesopelagic
Week #14
Hide & seek: Body shape & camouflage
Midwater predators:
y Rely on vision
y Weak muscles, poor swimmers, few defense structures (too heavy)
Midwater camouflage:
y Countershade
y Translucent, red or black y Reduction of silhouette
y Lateral compression
y Counterillumination
Eddie Widder
Abralia sp.
Bioluminescence
y Most midwater critters are bioluminescent
y Photophores (light organs)
y Counterillumination: produce
light that breaks up silhouette
and helps animal blend w/
background light
Firefly squid
Video…
Bathypelagic and Abyssopelagic
y < 5% of food produced in photic zone y No vertical migration, why?
y Too far, too much energy
y Fish are larger than mesopelagic fish
y E to growth & reproduce late
Huge mouths & expandable stomachs
Periphylla periphylla video…
A.K. Morris, Ph.D.
Lecture #16 (part 2)
Week #14
© Eddie Widder
Gulper Eel
Deep Sea Anglerfish
Reproduction
in the deep:
Hard to find a mate
Adaptations:
1. Hermaphroditism
2. Communication
y
3.
Light or pheromones
Male parasitism
male “parasitism”
© Bruce Robison
© Eddie Widder
PRESSURE:
y Need specialized enzymes or chemical stabilizers
y Pressure limits depth range
Benthos (sea bottom)
y Advantage: food accumulates
y Lower in nutrients, but more volume
y Deepest fish @ 27,460’
y Almost impossible to bring things to the surface
Diversity:
Gigantism
y Many spp in deep‐sea are much larger than cousins in shallows
Whale falls:
y Dead whales:
important source of E
y Huge input, but temporary
y bottom scavengers:
y Rattails
y cusk eels
y hagfish
A.K. Morris, Ph.D.
Lecture #16 (part 2)
Week #14
Bacteria
y Are they different?
y Alvin’s lunch:
y 1968 multimillion dollar oops.
y 10 mos. Later
y Bacteria different in deep sea
Hydrothermal vents
Bacteria
y Adapted to pressure
y 1977 geologists observe hydrothermal vents
y Slower y 1000X longer to decompose
y Free‐living, symbiotic, etc.
y Chemosynthetic bacteria in large #s in sediment
www.marum.de
Hydrothermal vents
•
•
•
•
Rich biological community
Most spp. new to science
Similar patterns: West Pacific, Mid-Atlantic
Contrary to William Forbes ‘Azoic Theory’
(deeper than 2000 ft, no life)
A.K. Morris, Ph.D.
Environmental Factors
y Hot, mineral‐rich H2O from cracks in sea floor
y Up to 300°C (Surrounding H2O ~ 2°C)
Lecture #16 (part 2)
Week #14
Fig. 16.28
y H2O heated up & rises w/ dissolved minerals
Hydrothermal vent video…
Chemosynthesis
y HIGH primary productivity
y Mineral rich water Æ H2S for chemosynthetic bacteria
y Produce organic matter using chemical Energy
Using bacteria
y Filter out bacteria
y Symbiosis: maintain bacteria in tissues
y Provide w/ H2S & CO2
Archaea & Bacteria
y Riftia (tubeworms)
• Some Archaea live >110C
(230F)
– Highest temp of living org
Cold Seeps
y Communities relying on chemosynthetic bacteria but NOT @ plate edge
y Worms & mussels dominate
y Cold methane seeps from bottom
y Not hot like vents
y 400‐6000m
Cold seeps video…
A.K. Morris, Ph.D.
Related documents
1.5--Day 4--Composition of Functions
1.5--Day 4--Composition of Functions
Dr. X and the Quest for Food Safety: Understanding
Dr. X and the Quest for Food Safety: Understanding
Life on the sea floor - National Oceanography Centre
Life on the sea floor - National Oceanography Centre
The number of food poisoning bacteria doubles every 10 minutes.
The number of food poisoning bacteria doubles every 10 minutes.
Video - OnCourse
Video - OnCourse
Extremophile ppt JV[1].
Extremophile ppt JV[1].
Unit Vocabulary: Diseases
Unit Vocabulary: Diseases
Bacteria Cell Structure and Function
Bacteria Cell Structure and Function
The Formation of Molecules Necessary for Life
The Formation of Molecules Necessary for Life
Bacterial Growth
Bacterial Growth
Plant Cells Animal Cells Respiration Nucleus • contain chloroplasts
Plant Cells Animal Cells Respiration Nucleus • contain chloroplasts
II. The animals of the Mesopelagic Zone (often called midwater
II. The animals of the Mesopelagic Zone (often called midwater