Dissipation of the energy imparted by mid-latitude storms in the Southern Ocean
Dissipation of the energy imparted by mid-latitude storms in the Southern Ocean
The aim of this study is to clarify the role of the Southern Ocean storms on interior mixing and meridional overturning circulation. A periodic and idealized numerical model has been designed to represent the key physical processes of a zonal portion of the Southern Ocean located between 70 and 40°?S. It incorporates physical ingredients deemed essential for Southern Ocean functioning: rough topography, seasonally varying air–sea fluxes, and high-latitude storms with analytical form. The forcing strategy ensures that the time mean wind stress is the same between the different simulations, so the effect of the storms on the mean wind stress and resulting impacts on the Southern Ocean dynamics are not considered in this study. Level and distribution of mixing attributable to high-frequency winds are quantified and compared to those generated by eddy–topography interactions and dissipation of the balanced flow. Results suggest that (1) the synoptic atmospheric variability alone can generate the levels of mid-depth dissipation frequently observed in the Southern Ocean (10?10–10?9?W?kg?1) and (2) the storms strengthen the overturning, primarily through enhanced mixing in the upper 300?m, whereas deeper mixing has a minor effect. The sensitivity of the results to horizontal resolution (20, 5, 2 and 1?km), vertical resolution and numerical choices is evaluated. Challenging issues concerning how numerical models are able to represent interior mixing forced by high-frequency winds are exposed and discussed, particularly in the context of the overturning circulation. Overall, submesoscale-permitting ocean modeling exhibits important delicacies owing to a lack of convergence of key components of its energetics even when reaching ?x?=??1?km.
743-769
Jouanno, Julien
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Capet, Xavier
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Madec, Gurvac
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Roullet, Guillaume
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Klein, Patrice
e391cce8-4760-459c-a9e7-e9dfe36a8156
Jouanno, Julien
f4e976db-5a36-4fd5-9db0-acd28c38b13e
Capet, Xavier
c717af64-fc36-4ef9-92ba-90bc22ab9eb4
Madec, Gurvac
6faf239b-9dad-41fd-a962-bbf523dffc03
Roullet, Guillaume
fc8caaf7-9206-4f56-b4ea-b49262bbc58f
Klein, Patrice
e391cce8-4760-459c-a9e7-e9dfe36a8156
Jouanno, Julien, Capet, Xavier, Madec, Gurvac, Roullet, Guillaume and Klein, Patrice
(2016)
Dissipation of the energy imparted by mid-latitude storms in the Southern Ocean.
Ocean Science, 12 (3), .
(doi:10.5194/os-12-743-2016).
Abstract
The aim of this study is to clarify the role of the Southern Ocean storms on interior mixing and meridional overturning circulation. A periodic and idealized numerical model has been designed to represent the key physical processes of a zonal portion of the Southern Ocean located between 70 and 40°?S. It incorporates physical ingredients deemed essential for Southern Ocean functioning: rough topography, seasonally varying air–sea fluxes, and high-latitude storms with analytical form. The forcing strategy ensures that the time mean wind stress is the same between the different simulations, so the effect of the storms on the mean wind stress and resulting impacts on the Southern Ocean dynamics are not considered in this study. Level and distribution of mixing attributable to high-frequency winds are quantified and compared to those generated by eddy–topography interactions and dissipation of the balanced flow. Results suggest that (1) the synoptic atmospheric variability alone can generate the levels of mid-depth dissipation frequently observed in the Southern Ocean (10?10–10?9?W?kg?1) and (2) the storms strengthen the overturning, primarily through enhanced mixing in the upper 300?m, whereas deeper mixing has a minor effect. The sensitivity of the results to horizontal resolution (20, 5, 2 and 1?km), vertical resolution and numerical choices is evaluated. Challenging issues concerning how numerical models are able to represent interior mixing forced by high-frequency winds are exposed and discussed, particularly in the context of the overturning circulation. Overall, submesoscale-permitting ocean modeling exhibits important delicacies owing to a lack of convergence of key components of its energetics even when reaching ?x?=??1?km.
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Accepted/In Press date: 25 April 2016
e-pub ahead of print date: 1 June 2016
Organisations:
Marine Systems Modelling
Identifiers
Local EPrints ID: 398550
URI: http://eprints.soton.ac.uk/id/eprint/398550
ISSN: 1812-0792
PURE UUID: 5091d3e8-6f1a-417d-8aa0-d811ed019514
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Date deposited: 26 Jul 2016 09:50
Last modified: 15 Mar 2024 01:35
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Author:
Julien Jouanno
Author:
Xavier Capet
Author:
Gurvac Madec
Author:
Guillaume Roullet
Author:
Patrice Klein
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