Southern Ocean transformation in a coupled model with
and without eddy mass fluxes
Southern Ocean transformation in a coupled model with
and without eddy mass fluxes
A coupled air–sea general circulation model is used to simulate the global circulation. Different parameterizations of lateral mixing in the ocean by eddies, horizontal, isopycnal, and isopycnal plus eddy advective flux, are compared from the perspective of water mass transformation in the Southern Ocean. The different mixing physics imply different buoyancy equilibria in the surface mixed layer, different transformations, and therefore a variety of meridional overturning streamfunctions. The coupled-model approach avoids strong artificial water mass transformation associated with relaxation to prescribed mixed layer conditions. Instead, transformation results from the more physical non-local, nonlinear interdependence of sea-surface temperature, air–sea fluxes, and circulation in the model’s atmosphere and ocean. The development of a stronger mid-depth circulation cell and associated upwelling when eddy fluxes are present, is examined. The strength of overturning is diagnosed in density coordinates using the transformation framework.
554-565
Speer, Kevin
4a385e5b-2710-423e-aebc-a3bc14e37a15
Guilyard, Eric
caea5e1a-910f-4281-8941-4546f28fc598
Madec, Gurvan
ffb28deb-4bbd-4a4c-914f-492f813e4864
2000
Speer, Kevin
4a385e5b-2710-423e-aebc-a3bc14e37a15
Guilyard, Eric
caea5e1a-910f-4281-8941-4546f28fc598
Madec, Gurvan
ffb28deb-4bbd-4a4c-914f-492f813e4864
Speer, Kevin, Guilyard, Eric and Madec, Gurvan
(2000)
Southern Ocean transformation in a coupled model with
and without eddy mass fluxes.
Tellus, 52A (5), .
Abstract
A coupled air–sea general circulation model is used to simulate the global circulation. Different parameterizations of lateral mixing in the ocean by eddies, horizontal, isopycnal, and isopycnal plus eddy advective flux, are compared from the perspective of water mass transformation in the Southern Ocean. The different mixing physics imply different buoyancy equilibria in the surface mixed layer, different transformations, and therefore a variety of meridional overturning streamfunctions. The coupled-model approach avoids strong artificial water mass transformation associated with relaxation to prescribed mixed layer conditions. Instead, transformation results from the more physical non-local, nonlinear interdependence of sea-surface temperature, air–sea fluxes, and circulation in the model’s atmosphere and ocean. The development of a stronger mid-depth circulation cell and associated upwelling when eddy fluxes are present, is examined. The strength of overturning is diagnosed in density coordinates using the transformation framework.
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Published date: 2000
Organisations:
National Oceanography Centre,Southampton
Identifiers
Local EPrints ID: 64844
URI: http://eprints.soton.ac.uk/id/eprint/64844
ISSN: 0280-6495
PURE UUID: ffe5f5ef-aa95-4954-8d56-928dc5dd94cd
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Date deposited: 16 Jan 2009
Last modified: 08 Jan 2022 19:08
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Contributors
Author:
Kevin Speer
Author:
Eric Guilyard
Author:
Gurvan Madec
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