Cushman-Roisin, Benoît
[Dartmouth College]
Deleersnijder, Eric
[UCL]
(eng)
The analytical solution is derived for rotational frictional flow in a shallow layer of fluid in which the top and bottom Ekman layers join without leaving a frictionless interior. This vertical structure has significant implications for the horizontal flow. In particular, for a layer of water subjected to both a surface wind stress and bottom friction, the vorticity of the horizontal flow is a function not only of the curl of the wind stress (the classical result for deep water known as Ekman pumping) but also of its divergence. The importance of this divergence term peaks for a water depth around 3 times the Ekman layer thickness. This means that a curl-free but non-uniform wind stress on a shallow sea or lake can, through the dual action of rotation and friction, generate vorticity in the wind-driven currents. We also find that the reduction of three-dimensional dynamics to a two-dimensional model is more subtle than one could have anticipated and needs to be approached with utmost care. Taking the bottom stress as dependent solely on the depth-averaged flow, even with some veering, is not appropriate. The bottom stress ought to include a component proportional to the surface stress, which is negligible for large depths but increases with decreasing water depth.
- Bennetts D. A., Hocking L. M., On Nonlinear Ekman and Stewartson Layers in a Rotating Fluid, 10.1098/rspa.1973.0074
- Cheng Ralph T., Powell Thomas M., Dillon Thomas M., Numerical models of wind-driven circulation in lakes, 10.1016/0307-904x(76)90035-4
- Cushman-Roisin B, Beckers J-M (2011) Introduction to geophysical fluid dynamics–physical and numerical aspects, 2nd edn. Academic Press, New York
- Ekman VW (1923) Über Horizontalzirkulation bei winderzeugten Meeresströmungen. Arkiv Mat Astr Fysik 17:26
- Forristall George Z., Three-dimensional structure of storm-generated currents, 10.1029/jc079i018p02721
- Heaps N. S., A Two-Dimensional Numerical Sea Model, 10.1098/rsta.1969.0041
- JELESNIANSKI CHESTER P., “BOTTOM STRESS TIME-HISTORY” IN LINEARIZED EQUATIONS OF MOTION FOR STORM SURGES1, 10.1175/1520-0493(1970)098<0462:bsthil>2.3.co;2
- Józsa János, On the internal boundary layer related wind stress curl and its role in generating shallow lake circulations, 10.2478/johh-2014-0004
- Lentz Steve, Guza R. T., Elgar Steve, Feddersen Falk, Herbers T. H. C., Momentum balances on the North Carolina inner shelf, 10.1029/1999jc900101
- Lick W, Numerical Modeling of Lake Currents, 10.1146/annurev.ea.04.050176.000405
- Lynch Daniel R., Officer Charles B., Analytic test cases for three-dimensional hydrodynamic models, 10.1002/fld.1650050604
- Nihoul Jacques C.J., Three-dimensional model of tides and storm surges in a shallow well-mixed continental sea, 10.1016/0377-0265(77)90014-8
- PRICE J. F., WELLER R. A., SCHUDLICH R. R., Wind-Driven Ocean Currents and Ekman Transport, 10.1126/science.238.4833.1534
- Schwab David J., Numerical Simulation of Low-Frequency Current Fluctuations in Lake Michigan, 10.1175/1520-0485(1983)013<2213:nsolfc>2.0.co;2
- Weisberg Robert H., Zheng Lianyuan, Hurricane storm surge simulations comparing three-dimensional with two-dimensional formulations based on an Ivan-like storm over the Tampa Bay, Florida region : STORM SURGE SIMULATIONS FOR TAMPA BAY, 10.1029/2008jc005115
- Welander P (1957) Wind action on a shallow sea: some generalizations of Ekman’s theory. Tellus 9:45–52
Référence bibliographique |
Cushman-Roisin, Benoît ; Deleersnijder, Eric. To-to-bottom Ekman Layer and its implications for shallow rotating flows. In: Environmental Fluid Mechanics (Dordrecht, 2001), Vol. 19, p. 1105-1119 (2019) |
Permalien |
https://hdl.handle.net/2078.1/218385 |