Subtropical dipole modes simulated in a coupled general circulation model

The growth and decay mechanisms of subtropical dipole modes in the southern Indian and South Atlantic Oceans and their impacts on southern African rainfall are investigated using results from a coupled general circulation model originally developed for predicting tropical climate variations. The sec...

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Main Authors: Morioka, Y., Tozuka, T., Masson, S., /Terray, Pascal, Luo, J. J., Yamagata, T.
Format: Text
Language:English
Published: 2012
Subjects:
South Atlantic Ocean
Online Access:https://www.documentation.ird.fr/hor/fdi:010057045
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spelling ftird:oai:ird.fr:fdi:010057045 2024-09-15T18:36:28+00:00 Subtropical dipole modes simulated in a coupled general circulation model Morioka, Y. Tozuka, T. Masson, S. /Terray, Pascal Luo, J. J. Yamagata, T. 2012 https://www.documentation.ird.fr/hor/fdi:010057045 EN eng https://www.documentation.ird.fr/hor/fdi:010057045 oai:ird.fr:fdi:010057045 Morioka Y., Tozuka T., Masson S., Terray Pascal, Luo J. J., Yamagata T. Subtropical dipole modes simulated in a coupled general circulation model. 2012, 25 (12), p. 4029-4047 text 2012 ftird 2024-08-15T05:57:42Z The growth and decay mechanisms of subtropical dipole modes in the southern Indian and South Atlantic Oceans and their impacts on southern African rainfall are investigated using results from a coupled general circulation model originally developed for predicting tropical climate variations. The second (most) dominant mode of interannual sea surface temperature (SST) variations in the southern Indian (South Atlantic) Ocean represents a northeast-southwest oriented dipole, now called subtropical dipole mode. The positive (negative) SST interannual anomaly pole starts to grow in austral spring and reaches its peak in February. In austral late spring, the suppressed (enhanced) latent heat flux loss associated with the variations in the subtropical high causes a thinner (thicker) than normal mixed layer thickness that, in turn, enhances (reduces) the warming of the mixed layer by the climatological shortwave radiation. The positive (negative) pole gradually decays in austral fall because the mixed layer cooling by the entrainment is enhanced (reduced), mostly owing to the larger (smaller) temperature difference between the mixed layer and the entrained water. The increased (decreased) latent heat loss due to the warmer (colder) SST also contributes to the decay of the positive (negative) pole. Although further verification using longer observational data is required, the present coupled model suggests that the South Atlantic subtropical dipole may play a more important role in rainfall variations over the southern African region than the Indian Ocean subtropical dipole. Text South Atlantic Ocean IRD (Institute de recherche pour le développement): Horizon
institution Open Polar
collection IRD (Institute de recherche pour le développement): Horizon
op_collection_id ftird
language English
description The growth and decay mechanisms of subtropical dipole modes in the southern Indian and South Atlantic Oceans and their impacts on southern African rainfall are investigated using results from a coupled general circulation model originally developed for predicting tropical climate variations. The second (most) dominant mode of interannual sea surface temperature (SST) variations in the southern Indian (South Atlantic) Ocean represents a northeast-southwest oriented dipole, now called subtropical dipole mode. The positive (negative) SST interannual anomaly pole starts to grow in austral spring and reaches its peak in February. In austral late spring, the suppressed (enhanced) latent heat flux loss associated with the variations in the subtropical high causes a thinner (thicker) than normal mixed layer thickness that, in turn, enhances (reduces) the warming of the mixed layer by the climatological shortwave radiation. The positive (negative) pole gradually decays in austral fall because the mixed layer cooling by the entrainment is enhanced (reduced), mostly owing to the larger (smaller) temperature difference between the mixed layer and the entrained water. The increased (decreased) latent heat loss due to the warmer (colder) SST also contributes to the decay of the positive (negative) pole. Although further verification using longer observational data is required, the present coupled model suggests that the South Atlantic subtropical dipole may play a more important role in rainfall variations over the southern African region than the Indian Ocean subtropical dipole.
format Text
author Morioka, Y.
Tozuka, T.
Masson, S.
/Terray, Pascal
Luo, J. J.
Yamagata, T.
spellingShingle Morioka, Y.
Tozuka, T.
Masson, S.
/Terray, Pascal
Luo, J. J.
Yamagata, T.
Subtropical dipole modes simulated in a coupled general circulation model
author_facet Morioka, Y.
Tozuka, T.
Masson, S.
/Terray, Pascal
Luo, J. J.
Yamagata, T.
author_sort Morioka, Y.
title Subtropical dipole modes simulated in a coupled general circulation model
title_short Subtropical dipole modes simulated in a coupled general circulation model
title_full Subtropical dipole modes simulated in a coupled general circulation model
title_fullStr Subtropical dipole modes simulated in a coupled general circulation model
title_full_unstemmed Subtropical dipole modes simulated in a coupled general circulation model
title_sort subtropical dipole modes simulated in a coupled general circulation model
publishDate 2012
url https://www.documentation.ird.fr/hor/fdi:010057045
genre South Atlantic Ocean
genre_facet South Atlantic Ocean
op_relation https://www.documentation.ird.fr/hor/fdi:010057045
oai:ird.fr:fdi:010057045
Morioka Y., Tozuka T., Masson S., Terray Pascal, Luo J. J., Yamagata T. Subtropical dipole modes simulated in a coupled general circulation model. 2012, 25 (12), p. 4029-4047
_version_ 1810480134361186304

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