The effect of rotation on double diffusive convection: perspectives from linear stability analysis

Diffusive convection can occur when two constituents of a stratified fluid have opposing effects on its stratification and different molecular diffusivities. This form of convection arises for the particular temperature and salinity stratification in the Arctic Ocean and is relevant to heat fluxes....

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Bibliographic Details
Published in:Journal of Physical Oceanography
Main Authors: Liang, Y., Carpenter, J., Timmermans, M.
Format: Article in Journal/Newspaper
Language:English
Published: AMS 2021
Subjects:
Arctic
Arctic Ocean
Tilting
Online Access:https://publications.hereon.de/id/40361
https://publications.hzg.de/id/40361
https://www.hereon.de/imperia/md/content/gkss/zentrale_einrichtungen/bibliothek/journals/2021/liang__40361.pdf
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spelling fthzgzmk:oai:publications.hereon.de:40361 2023-06-11T04:09:14+02:00 The effect of rotation on double diffusive convection: perspectives from linear stability analysis Liang, Y. Carpenter, J. Timmermans, M. 2021 https://publications.hereon.de/id/40361 https://publications.hzg.de/id/40361 https://www.hereon.de/imperia/md/content/gkss/zentrale_einrichtungen/bibliothek/journals/2021/liang__40361.pdf en eng AMS https://dx.doi.org/10.1175/JPO-D-21-0060.1 urn:issn:0022-3670 https://publications.hereon.de/id/40361 https://publications.hzg.de/id/40361 https://www.hereon.de/imperia/md/content/gkss/zentrale_einrichtungen/bibliothek/journals/2021/liang__40361.pdf info:eu-repo/semantics/openAccess open_access oa_gruen issn:0022-3670 Liang, Y.; Carpenter, J.; Timmermans, M.: The effect of rotation on double diffusive convection: perspectives from linear stability analysis. In: Journal of Physical Oceanography. Vol. 51 (2021) 11, 3335 - 3346. (DOI: /10.1175/JPO-D-21-0060.1) info:eu-repo/semantics/article Zeitschrift Artikel 2021 fthzgzmk https://doi.org/10.1175/JPO-D-21-0060.1 2023-05-28T23:25:20Z Diffusive convection can occur when two constituents of a stratified fluid have opposing effects on its stratification and different molecular diffusivities. This form of convection arises for the particular temperature and salinity stratification in the Arctic Ocean and is relevant to heat fluxes. Previous studies have suggested that planetary rotation may influence diffusive-convective heat fluxes, although the precise physical mechanisms and regime of rotational influence are not well understood. A linear stability analysis of a temperature and salinity interface bounded by two mixed layers is performed here to understand the stability properties of a diffusive-convective system, and in particular the transition from non-rotating to rotationally-controlled heat transfer. Rotation is shown to stabilize diffusive convection by increasing the critical Rayleigh number to initiate instability. In the rotationally-controlled regime, a −4/3 power law is found between the critical Rayleigh number and the Ekman number, similar to the scaling for rotating thermal convection. The transition from non-rotating to rotationally-controlled convection, and associated drop in heat fluxes, is predicted to occur when the thermal interfacial thickness exceeds about 4 times the Ekman layer thickness. A vorticity budget analysis indicates how baroclinic vorticity production is counteracted by the tilting of planetary vorticity by vertical shear, which accounts for the stabilization effect of rotation. Finally, direct numerical simulations yield generally good agreement with the linear stability analysis. This study, therefore, provides a theoretical framework for classifying regimes of rotationally-controlled diffusive-convective heat fluxes, such as may arise in some regions of the Arctic Ocean. Article in Journal/Newspaper Arctic Arctic Ocean Hereon Publications (Helmholtz-Zentrum) Arctic Arctic Ocean Tilting ENVELOPE(-54.065,-54.065,49.700,49.700) Journal of Physical Oceanography
institution Open Polar
collection Hereon Publications (Helmholtz-Zentrum)
op_collection_id fthzgzmk
language English
description Diffusive convection can occur when two constituents of a stratified fluid have opposing effects on its stratification and different molecular diffusivities. This form of convection arises for the particular temperature and salinity stratification in the Arctic Ocean and is relevant to heat fluxes. Previous studies have suggested that planetary rotation may influence diffusive-convective heat fluxes, although the precise physical mechanisms and regime of rotational influence are not well understood. A linear stability analysis of a temperature and salinity interface bounded by two mixed layers is performed here to understand the stability properties of a diffusive-convective system, and in particular the transition from non-rotating to rotationally-controlled heat transfer. Rotation is shown to stabilize diffusive convection by increasing the critical Rayleigh number to initiate instability. In the rotationally-controlled regime, a −4/3 power law is found between the critical Rayleigh number and the Ekman number, similar to the scaling for rotating thermal convection. The transition from non-rotating to rotationally-controlled convection, and associated drop in heat fluxes, is predicted to occur when the thermal interfacial thickness exceeds about 4 times the Ekman layer thickness. A vorticity budget analysis indicates how baroclinic vorticity production is counteracted by the tilting of planetary vorticity by vertical shear, which accounts for the stabilization effect of rotation. Finally, direct numerical simulations yield generally good agreement with the linear stability analysis. This study, therefore, provides a theoretical framework for classifying regimes of rotationally-controlled diffusive-convective heat fluxes, such as may arise in some regions of the Arctic Ocean.
format Article in Journal/Newspaper
author Liang, Y.
Carpenter, J.
Timmermans, M.
spellingShingle Liang, Y.
Carpenter, J.
Timmermans, M.
The effect of rotation on double diffusive convection: perspectives from linear stability analysis
author_facet Liang, Y.
Carpenter, J.
Timmermans, M.
author_sort Liang, Y.
title The effect of rotation on double diffusive convection: perspectives from linear stability analysis
title_short The effect of rotation on double diffusive convection: perspectives from linear stability analysis
title_full The effect of rotation on double diffusive convection: perspectives from linear stability analysis
title_fullStr The effect of rotation on double diffusive convection: perspectives from linear stability analysis
title_full_unstemmed The effect of rotation on double diffusive convection: perspectives from linear stability analysis
title_sort effect of rotation on double diffusive convection: perspectives from linear stability analysis
publisher AMS
publishDate 2021
url https://publications.hereon.de/id/40361
https://publications.hzg.de/id/40361
https://www.hereon.de/imperia/md/content/gkss/zentrale_einrichtungen/bibliothek/journals/2021/liang__40361.pdf
long_lat ENVELOPE(-54.065,-54.065,49.700,49.700)
geographic Arctic
Arctic Ocean
Tilting
geographic_facet Arctic
Arctic Ocean
Tilting
genre Arctic
Arctic Ocean
genre_facet Arctic
Arctic Ocean
op_source issn:0022-3670
Liang, Y.; Carpenter, J.; Timmermans, M.: The effect of rotation on double diffusive convection: perspectives from linear stability analysis. In: Journal of Physical Oceanography. Vol. 51 (2021) 11, 3335 - 3346. (DOI: /10.1175/JPO-D-21-0060.1)
op_relation https://dx.doi.org/10.1175/JPO-D-21-0060.1
urn:issn:0022-3670
https://publications.hereon.de/id/40361
https://publications.hzg.de/id/40361
https://www.hereon.de/imperia/md/content/gkss/zentrale_einrichtungen/bibliothek/journals/2021/liang__40361.pdf
op_rights info:eu-repo/semantics/openAccess
open_access
oa_gruen
op_doi https://doi.org/10.1175/JPO-D-21-0060.1
container_title Journal of Physical Oceanography
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