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How physical forces influence marine biota

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Title: How physical forces influence marine biota


1
How physical forces influence marine biota
  • Factors that affect physical oceanographic
    processes
  • ll. Very large scale currents
  • III. Large-Scale currents- Gyres
  • lV. Upwelling
  • IV. Coastal eddies
  • IV. El Nino

2
Sun glint in the Mediterranean Sea
3
What drives all this motion?
1) Solar Radiation
2) Rotation of the Earth
4
Rotation of the earth produces
Coriolis Force
(gravitational, pressure gradient, frictional,
Coriolis)
Earth spins west to east (eastward)
Eastward velocity is greatest at equator and
decreases poleward
5
Coriolis Force causes path of a moving object
to be deflected to the right in the NH and to the
left in SH relative to the surface of the earth
6
Solar Radiation
1) Sun drives ocean circulation through the
circulation of the Atmosphere- winds
  • Energy transferred from winds to the upper layers
    of the ocean

2) Sun drives circulation by causing variation in
Temp. salinity, which changes density
  • Changes in Temp. are caused by fluxes of heat
    across sea-air interface
  • Changes in salinity caused by addition or removal
    of FW- evaporation or precipitation
  • If surface water becomes more dense than
    underlying water, it sinks

7
Which factors create oceanic currents?
1) Solar Radiation
Wind
2) Rotation of the Earth
Coriolis Force
Moving bodies (e.g. water masses) to be deflected
from their initial trajectory
8
World Surface Currents
9
Part II Very large-scale current generation
Thermohaline circulation
10
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11
Part III Large-scale current generation
What processes create gyres?
Gyres force coastal currents and related
processes
12
Wind moves clockwise in the Atlantic Ocean
Ekman transport causes water to pile up in the
center of the Atlantic
Body of water moves 90? to the right of wind
direction
13
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14
Forcing of cold, more nutrient rich water to the
surface leads to an increase in primary
production.
15
Water movement creates differences in Sea Surface
Height
16
Geostrophic Flow
  • Flow driven by density differences
  • Density of seawater controlled by temperature and
    salinity
  • Temperature ? density ?
  • Salinity ? density ?

17
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18
Specific Volume of Seawater
  • S.V. 1/density 1/(g cm-3) cm3/g
  • volume occupied by one gram
  • When density is high specific volume is low

19
Specific volume affect sea surface height and
therefore currents
1 cm
100 cm
100g of 1 cm3/g
100g of 2 cm3/g
20
Geostrophic Flow(water flows around hills)
Warm, low salinity
Cold, high salinity
Sea Floor
21
Density Driven Flow
Geostrophic Flow caused by sloping sea
surfaces Pressure Gradient Force (PGF) The
force associated with the tendency for water to
flow downhill due to gravity. The PGF goes from
tall to short water columns. Increasing
temperature or decreasing salinity lowers the
density of seawater. For the same mass of water,
the less dense water column will be taller. The
net transport of water is 90 to the RIGHT of the
PGF in the northern hemisphere. The net transport
of water is 90 to the LEFT of the PGF in the
southern hemisphere. OR use the light on the
right rule. Place your right arm (left arm) in
the direction of the lighter, taller, water
column and you are looking down current in the
northern hemisphere (southern hemisphere).
22
Gyre Circulation
23
Implication Measuring Sea Surface Height (SSH)
can tell you the speed and direction of current
flow Satellites can measure accurately variation
in SSH at a 1-cm scale
Web Page SSH http//www-ccar.colorado.edu/real
time/gsfc_global-real-time_ssh/
24
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25
Western Boundary Currents
Why?
26
Western Boundary currents
27
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28
Part IV Upwelling
1) Organisms in photic zone die and sink-
worldwide
2) Deep, cold water is relatively rich in
nutrients
3) Upwelling Movement of cold, nutrient rich
water towards the surface
4) Areas of high primary production and
biomass-rich food webs
29
Equatorial upwelling
equator
30
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31
coastal upwelling northern hemisphere
wind from north
32
World Surface Currents
33
Upwelling California Current
http//www.montereybay.noaa.gov/sitechar/icons/phy
fi3.gif
34
upwelling variations
downwelling
upwelling
bottom currents
surface currents
Grantham et al., 2004, Nature
35
coastal downwelling northern hemisphere
wind from south
36
Marine Food Chains/Webs
  • Energy from primary production is transferred up
    the trophic chain
  • Each step is inefficient (90 energy is lost)
  • Shorter chains are more efficient at producing
    apex predators

37
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38
Bottom Up Control on the Marine Food Webs
hn
CO2
O2
Phytoplankton
Food Web
Plants
NUTS
Primary Secondary Production
Production
39
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40
Primary Production by Biome
Ryther (1969) Science
41
Marine Food Chains/Webs
  • Open ocean 90 area most of the NPP but
    little fish production
  • Coastal ocean 9.9 area 20 of the global NPP
    but ½ of the fish production
  • Upwelling systems 0.1 area little NPP but ½
    fish production

42
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44
CalCoFI Zooplankton Sampling
45
CalCoFIZooplankton
46
Seasonal Zooplankton
Zoo Winds
47
Seasonal Zooplankton
Zoo Winds
48
CalCoFI Zooplankton
Highest in the tongue of CA Current
49
The Upwelling Conveyor Belt
High Zoo
Low Zoo
Lower Zoo
High Chl
Low Chl
Lower Chl
High NUTS
Low NUTS
Sinking POM
Highest NUTS
50
CalCoFIZooplankton
Hi Zoos Low Temp ENSO connection All in
pre-1977
51
CalCoFI Zooplankton
70 Decline in 1970s
52
SURFACE WATERS HAVE WARMED IN Southern
California (Decadal Climate Regime Shift)
Scripps
gt 1o C Increase in Mean Annual Sea Water
Temperature 1975-2000
MEAN ANNUAL SURFACE TEMPERATURE
Santa Barbara
1960
1980
1990
YEAR
53
Temporal Changes in Biomass of Zooplankton
in So. Ca. Bight
80 Decline in Warming Event
54
Temporal Changes in Abundance of Reef
Fishes in So. Ca. Bight (data from 2
locations)
70 Decline in Warming Event
55
Pacific Decadal Oscillation
  • Evidence for just two full PDO cycles in the past
    century
  • "cool" PDO regimes prevailed from 1890-1924 and
    again from 1947-1976
  • "warm" PDO regimes dominated from 1925-1946 and
    from 1977 through (at least) the mid-1990s
  • Causes for the PDO are not currently known
  • Potential predictability for this climate
    oscillation are not known.
  • Some climate simulation models produce PDO-like
    oscillations, although often for different
    reasons.

56
The Upwelling Conveyor Belt/Climate change
High Zoo
Low Zoo
Lower Zoo
High Chl
Low Chl
Lower Chl
High NUTS
Low NUTS
Sinking POM
Highest NUTS
57
Oregon coastal upwelling
Grantham et al., 2004, Nature
58
  • Ocean dynamics directly and indirectly affect the
    spatial and temporal variability of organisms and
    the performance of organisms (especially egg and
    larval mortality)
  • Storms, for example, disperse larvae and destroy
    food patches and persistent wind-induced
    upwelling or anomalous currents along a coast can
    advect larvae to unsuitable
  • areas where growth and survivorship can be low or
    where returning to nearshore settlement habitat
    is impossible
  • At greater temporal and spatial scales, climatic
    events alter water mass distributions, water
    column structure, current patterns, and coastal
    upwelling of nutrient-rich water
  • These environmental perturbations affect
    movement, spawning, and recruitment patterns of
    fish populations

59
  • Large-scale physical processes producing
    mortality in the early pelagic phase of fishes
    and other marine organisms can be offset by
    smallerscale mechanisms
  • For example, coastal eddies, mesoscale features
    inherent in temporally and spatially variable
    current fields, can retain fishes during their
    pelagic phase and may enhance recruitment
  • Mary Nishimoto and Libe Washburn (UCSB)
  • Sampled with mid-water trawls California
    smoothtongue, northern
  • lampfish, Mexican lampfish, Pacific hake, and
    rockfishes
  • Latter 2 taxa were represented by late-stage
    larvae and pelagic juveniles.
  • Small fishes of about 15 to 100 mm standard
    length (SL) important
  • forage for seabirds, marine mammals, piscivorous
    fishes including salmon

60
  • California Current System (CCS) is the eastern
    boundary current system of the North Pacific
  • Eddies, filaments, and meanders driven by
    variable winds and pressure gradients
    characterize the flow field over the shelf and
    offshore in the equatorward-flowing jet of the
    CCS
  • Mesoscale features result in part from headlands
    and bathymetry along the coast
  • Santa Barbara Channel is a transition region
    between the strong coastal upwelling regime
    extending northward from Point Conception to
    Washington and the warmer waters of the Southern
    California Bight.

61
  • A poleward, temperature-dependent pressure
    gradient tends to drive strong westward currents
    in the Channel
  • Opposing the pressure gradient are winds that
    tend to induce upwelling and drive eastward flow,
    especially in the southern Channel
  • When effects of wind and pressure gradients
    balance, the flow is cyclonic with westward flow
    along the northern boundary of the Channel and
    eastward flow along the Channel Islands, the
    southern boundary

62
  • Currents in the upper layers carry a diversity of
    fish species into the Santa Barbara Channel where
    many recruit to adult habitats

63
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67
Part V El Nino - Southern Oscillation
  • El Niño events are linked to
  • delayed and reduced phytoplankton productivity
  • reduced zooplankton biomass
  • increased mortality of coastal fishes during
    their planktonic larval phase

68
Normal Conditions
Warm, moist air rises in Indonesia
Air moves poleward towards South America
High pressure over S. America, Low over Indonesia
Creates SE Trade Winds
69
Normal Conditions
S-E Trade winds cause warm water to pile up in
the western Pacific
warm water
Indonesia/ Australia
S. America
cool water
70
El Nino Conditions
High/Low Pressure system weakens
Area that is normally dry
SE Trades stop or even reverse
warm water
Gradient in Sea Surface Height degenerates
Warm, nutrient-poor water moves east
71
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