Slope Control in Western Boundary CurrentsSource: Journal of Physical Oceanography:;2001:;Volume( 031 ):;issue: 011::page 3349DOI: 10.1175/1520-0485(2001)031<3349:SCIWBC>2.0.CO;2Publisher: American Meteorological Society
Abstract: An analytic solution is presented for the steady-state depth-averaged western boundary current flowing over the continental slope by combining three highly idealized models: the Stommel model, the Munk model, and the arrested topographic wave model. The main vorticity balance over the slope is between planetary vorticity advection and the slope-induced bottom stress torque, which is proportional to r?(h?1)x where r is the Rayleigh friction coefficient, h is the water depth, and ? is the meridional velocity. This slope-induced torque provides the necessary source of vorticity for poleward flow over the slope, its simple interpretation being that vorticity is produced because the bottom stress has to act over the seaward-deepening water column. The character of the solution depends on the slope α as well as on the assumed bottom drag coefficient, and the length scale of the boundary current is ?2r/(?α). It is further shown that, if the depth-averaged velocity flows along isobaths, then the stretching of water columns associated with cross-isobath geostrophic flow, which compensates bottom Ekman transport, is identical to the slope-induced torque by the geostrophic velocities.
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| contributor author | Lee, Sang-Ki | |
| contributor author | Pelegrí, J. L. | |
| contributor author | Kroll, John | |
| date accessioned | 2017-06-09T14:54:57Z | |
| date available | 2017-06-09T14:54:57Z | |
| date copyright | 2001/11/01 | |
| date issued | 2001 | |
| identifier issn | 0022-3670 | |
| identifier other | ams-29583.pdf | |
| identifier uri | http://onlinelibrary.yabesh.ir/handle/yetl/4166826 | |
| description abstract | An analytic solution is presented for the steady-state depth-averaged western boundary current flowing over the continental slope by combining three highly idealized models: the Stommel model, the Munk model, and the arrested topographic wave model. The main vorticity balance over the slope is between planetary vorticity advection and the slope-induced bottom stress torque, which is proportional to r?(h?1)x where r is the Rayleigh friction coefficient, h is the water depth, and ? is the meridional velocity. This slope-induced torque provides the necessary source of vorticity for poleward flow over the slope, its simple interpretation being that vorticity is produced because the bottom stress has to act over the seaward-deepening water column. The character of the solution depends on the slope α as well as on the assumed bottom drag coefficient, and the length scale of the boundary current is ?2r/(?α). It is further shown that, if the depth-averaged velocity flows along isobaths, then the stretching of water columns associated with cross-isobath geostrophic flow, which compensates bottom Ekman transport, is identical to the slope-induced torque by the geostrophic velocities. | |
| publisher | American Meteorological Society | |
| title | Slope Control in Western Boundary Currents | |
| type | Journal Paper | |
| journal volume | 31 | |
| journal issue | 11 | |
| journal title | Journal of Physical Oceanography | |
| identifier doi | 10.1175/1520-0485(2001)031<3349:SCIWBC>2.0.CO;2 | |
| journal fristpage | 3349 | |
| journal lastpage | 3360 | |
| tree | Journal of Physical Oceanography:;2001:;Volume( 031 ):;issue: 011 | |
| contenttype | Fulltext |