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Published byBeverly Carpenter Modified over 9 years ago
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Class 8. Oceans Figure: Ocean Depth (mean = 3.7 km)
bounded by continents deep: difficult to make observations Figure: Ocean Depth (mean = 3.7 km)
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Ship-measurements Only a limited area covered bounded by continents
deep: difficult to make observations Only a limited area covered
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SST from buoys drifter: can freely drift moored: anchor
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Ocean Surface Temperature from Remote Sensing (NOAA)
-2.0 C 16.1 cold water sinks warm - maximum insolation - albedo of water ~ 7% cold water sinks strong gradient towards the poles some structures: green cold tongue off the coast of california, Peru source NOAA
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Ocean Surface Salinity
Prep>Evap Evap>Prep strong gradient towards the poles some structures: green cold tongue off the coast of california, Peru
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ARGO: profiling the interior of the ocean (up to z=-2000 m)
drifter: can freely drift moored: anchor
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ARGO: profiling the interior of the ocean (up to z=-2000 m)
drifter: can freely drift moored: anchor Data products: Temperature, salinity and density
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Zonal average temperature in deep ocean
warm salty stratified lens of fluid abyss z>1000 m homogeneous mass of very cold water
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Schematic of vertical structure
convection in the upper layer causes a vertically well mixed layer strong vertical temperature gradient defines the thermocline note: analogy to thermal inversion in the atmosphere very cold water present below z<1000 m
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Thermal expansion: Sea-level transgression scenarios for Bangladesh
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Density (anomaly s), Temperature and Salinity
higher density salty water has a higher density fresh water show dip in density Fig. 9.2: Contours of seawater density anomalies (s=r-rref in kg/m3) rref = 1000 kg/m3 PSU = Practical Salinity Unit ≈ g/kg grams of salt per kg of solution
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Simplified equation of state (defined with respect to s0(T0,S0))
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Simplified equation of state (defined with respect to s0(T0,S0))
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Schematic of vertical structure
tendency due to radiative heating T = temperature F = heat flux (Wm-2) rw = density of water cw = heat capacity of water μ
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1000 depth (m) cold water - deep convection cold water upwelling 900S 900N 00 latitude
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P>E P<E 1000 depth (m) 900S 900N 00 latitude Low salinity if precipitation (P) exceeds evaporation (E)
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Thermohaline circulation
arctic sea ice
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Sea level height
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Which balances do apply in the ocean?
Hydrostatic balance -> yes Geostrophic balance? Thermal "wind"? Ekman pumping/suction?
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Rossby and Reynolds number in the ocean
Far away from the equator, e.g. latitude = 400, North-South length scale L = 2000 km (east-west larger) Velocity scale U = 0.1 m/s
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Pressure in the ocean mean density in water column high pressure
low pressure geef eventueel dp/dz
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Which sea level tilt is needed to explain U=0.1 m/s?
werk uit op bord Example 1: assume density is constant
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Geostrophic flow at depth
Example 2: assume density is NOT constant, but varies in the x,y directions => r(x,y)=rref+s(x,y) 1000 depth (m) 900S 900N 00 latitude 23 24 25 26 26.5 27 1. Taylor Proudman 2. Thermal wind
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Estimating the geostrophic wind from the density field: The dynamic method
This method allows for assessing geostrophic velocities relative to some reference level One can assume that at a "sufficiently" deep height ug=0 1. Taylor Proudman 2. Thermal wind
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Geostrophic flow at depth z
Example 3: I) assume density is NOT constant, but varies in the x,y directions => r(x,y)=rref+s(x,y) II) surface height is NOT constant 1. Taylor Proudman 2. Thermal wind
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Geostrophic flow Example 1: In the ocean geostrophic flow applies (not too close to equator) Pressure induced by surface height variations η Example 2: Horizontal density gradients cause a vertical change in the geostrophic flow velocity ("thermal" wind) Example 3: In principle both height and density variations may apply 1: p184, above 9-11 2: 7-16 3:
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Determining the ocean flow from floating plastic ducks?
1. Taylor Proudman 2. Thermal wind
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1. Taylor Proudman 2. Thermal wind
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1000 depth (m) cold water - deep convection cold water upwelling 900S 900N 00 latitude
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Ekman pumping/suction
1. Taylor Proudman 2. Thermal wind
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Wind-driven ocean flow
Equations with wind-stress
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Wind-driven ocean flow
Equations with wind-stress Split velocity in geostrophic ('g') and ageostrophic parts ('ag') e.g.
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Ekman transport
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Ekman pumping (downwards)/suction
X wind into the screen
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Ekman pumping (downwards)/suction
elevated sea level height in convergence area tropics midlatitudes
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Ekman pumping/suction due to wind stress
1. Taylor Proudman 2. Thermal wind
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Ekman pumping/suction Explanation
mass conservation
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Ekman pumping/suction Explanation
1. we do not assume that f is constant, but f=f(y) 2. variations in wind stress are much larger than in f
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Ekman pumping/suction Example
= 32 m/year
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Ekman pumping/suction from wind stress climatology
downward upward f=0
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