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Ekman layer at the bottom of the sea

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Presentation on theme: "Ekman layer at the bottom of the sea"— Presentation transcript:

1 Ekman layer at the bottom of the sea
For convenience, assume the bottom of the sea is flat and located at z=0, the governing equation and its general solution are the same as the surface case. Boundary conditions Z=0 (bottom of the sea) or As z-(into the interior) or

2 General solution: If z, VE0, i.e., A=0 If z=0, VE=-Vg=B We have Let

3 Let

4 Solution For z0,

5 The direction of the total currents
where The near bottom the total current is 45o to the left of the geostrophic current.

6

7 Transport at the top of the bottom Ekman layer
Assume , the solution can be written as Using the continuity equation

8 We have Since

9 Ekman pumping at the bottom.
Given the integral i.e., The vertical velocity at the top of the bottom boundary layer Ekman pumping at the bottom.

10 Wind-driven circulation II
●Wind pattern and oceanic gyres ●Sverdrup Relation ●Vorticity Equation

11

12

13 Surface current measurement from ship drift
Current measurements are harder to make than T&S The data are much sparse.

14 Surface current observations

15 Surface current observations

16

17

18 Drifting Buoy Data Assembly Center, Miami, Florida
Atlantic Oceanographic and Meteorological Laboratory, NOAA

19 Annual Mean Surface Current Pacific Ocean, 1995-2003
Drifting Buoy Data Assembly Center, Miami, Florida Atlantic Oceanographic and Meteorological Laboratory, NOAA

20

21 Schematic picture of the major surface currents of the world oceans
Note the anticyclonic circulation in the subtropics (the subtropical gyres)

22 Relation between surface winds and subtropical gyres

23 Surface winds and oceanic gyres: A more realistic view
Note that the North Equatorial Counter Current (NECC) is against the direction of prevailing wind.

24 Mean surface current tropical Atlantic Ocean
Note the North Equatorial Counter Current (NECC)

25 Consider the following balance in an ocean of depth h of flat bottom
Sverdrup Relation Consider the following balance in an ocean of depth h of flat bottom , Integrating vertically from –h to 0, we have (neglecting bottom stress and surface height change) (1) (2) where and Differentiating , we have Using continuity equation and , Sverdrup relation we have

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