The Antarctic Circumpolar Current in equilibrium

A simple channel-flow model is used to examine the equilibrium upper-ocean dynamics and thermodynamics of the Antarctic Circumpolar Current (ACC). The model consists of two zonally averaged, variable-temperature layers-a surface boundary layer and a thermocline layer-separated by a turbulent interfa...

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Main Authors: Gallego, B, Cessi, Paola, McWilliams, J C
Format: Article in Journal/Newspaper
Language:English
Published: eScholarship, University of California 2004
Subjects:
Antarctic
The Antarctic
Antarc*
Online Access:http://www.escholarship.org/uc/item/76w965hp
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record_format openpolar
spelling ftcdlib:qt76w965hp 2023-05-15T14:01:33+02:00 The Antarctic Circumpolar Current in equilibrium Gallego, B Cessi, Paola McWilliams, J C 1571 - 1587 2004-07-01 application/pdf http://www.escholarship.org/uc/item/76w965hp english eng eScholarship, University of California qt76w965hp http://www.escholarship.org/uc/item/76w965hp public Gallego, B; Cessi, Paola; & McWilliams, J C. (2004). The Antarctic Circumpolar Current in equilibrium. Journal of Physical Oceanography, 34(7), 1571 - 1587. UC San Diego: Retrieved from: http://www.escholarship.org/uc/item/76w965hp article 2004 ftcdlib 2016-04-02T18:30:50Z A simple channel-flow model is used to examine the equilibrium upper-ocean dynamics and thermodynamics of the Antarctic Circumpolar Current (ACC). The model consists of two zonally averaged, variable-temperature layers-a surface boundary layer and a thermocline layer-separated by a turbulent interface. Weak air-sea heat flux, determined by relaxation to a prescribed atmospheric temperature, determines the leading-order temperature structure in the oceanic surface layer. The equilibrium thermal structure in the interior is mostly determined by a dominant balance between the meridional transport due to the wind-driven Eulerian mean circulation and the heat flux due to the baroclinic eddies. The resulting latitudinal temperature gradient depends on both the wind and the atmospheric temperature forcing and sustains the geostrophic zonal flow. Consideration of the next-order balance for the oceanic surface temperature results in an air-sea heat flux proportional to the magnitude of the residual flow. The residual meridional circulation ( Eulerian mean plus eddy-induced) is necessary to balance small diabatic sources and sinks of heat. Therefore, it depends on the processes of vertical diffusion, boundary layer entrainment/detrainment, and, on the polar flank, convection. In the absence of substantial lateral diffusion, the leading-order balance of weak residual circulation implies a very weak meridional heat transport across the ACC and a correspondingly weak differential heat exchange to the atmosphere. This limitation can be eased if the lateral diffusive flux of temperature in the surface layer becomes as large as the adiabatic eddy transport. Article in Journal/Newspaper Antarc* Antarctic University of California: eScholarship Antarctic The Antarctic
institution Open Polar
collection University of California: eScholarship
op_collection_id ftcdlib
language English
description A simple channel-flow model is used to examine the equilibrium upper-ocean dynamics and thermodynamics of the Antarctic Circumpolar Current (ACC). The model consists of two zonally averaged, variable-temperature layers-a surface boundary layer and a thermocline layer-separated by a turbulent interface. Weak air-sea heat flux, determined by relaxation to a prescribed atmospheric temperature, determines the leading-order temperature structure in the oceanic surface layer. The equilibrium thermal structure in the interior is mostly determined by a dominant balance between the meridional transport due to the wind-driven Eulerian mean circulation and the heat flux due to the baroclinic eddies. The resulting latitudinal temperature gradient depends on both the wind and the atmospheric temperature forcing and sustains the geostrophic zonal flow. Consideration of the next-order balance for the oceanic surface temperature results in an air-sea heat flux proportional to the magnitude of the residual flow. The residual meridional circulation ( Eulerian mean plus eddy-induced) is necessary to balance small diabatic sources and sinks of heat. Therefore, it depends on the processes of vertical diffusion, boundary layer entrainment/detrainment, and, on the polar flank, convection. In the absence of substantial lateral diffusion, the leading-order balance of weak residual circulation implies a very weak meridional heat transport across the ACC and a correspondingly weak differential heat exchange to the atmosphere. This limitation can be eased if the lateral diffusive flux of temperature in the surface layer becomes as large as the adiabatic eddy transport.
format Article in Journal/Newspaper
author Gallego, B
Cessi, Paola
McWilliams, J C
spellingShingle Gallego, B
Cessi, Paola
McWilliams, J C
The Antarctic Circumpolar Current in equilibrium
author_facet Gallego, B
Cessi, Paola
McWilliams, J C
author_sort Gallego, B
title The Antarctic Circumpolar Current in equilibrium
title_short The Antarctic Circumpolar Current in equilibrium
title_full The Antarctic Circumpolar Current in equilibrium
title_fullStr The Antarctic Circumpolar Current in equilibrium
title_full_unstemmed The Antarctic Circumpolar Current in equilibrium
title_sort antarctic circumpolar current in equilibrium
publisher eScholarship, University of California
publishDate 2004
url http://www.escholarship.org/uc/item/76w965hp
op_coverage 1571 - 1587
geographic Antarctic
The Antarctic
geographic_facet Antarctic
The Antarctic
genre Antarc*
Antarctic
genre_facet Antarc*
Antarctic
op_source Gallego, B; Cessi, Paola; & McWilliams, J C. (2004). The Antarctic Circumpolar Current in equilibrium. Journal of Physical Oceanography, 34(7), 1571 - 1587. UC San Diego: Retrieved from: http://www.escholarship.org/uc/item/76w965hp
op_relation qt76w965hp
http://www.escholarship.org/uc/item/76w965hp
op_rights public
_version_ 1766271389997727744

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