Editorial Type:
Article
Article Type:
Research Article

Relations between Annular Modes and the Mean State: Southern Hemisphere Winter

Francis Codron Laboratoire de Météorologie Dynamique, Université Pierre et Marie Curie-Paris/CNRS, Paris, France

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01 Sep 2007
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Jets and Annular Structures in Geophysical Fluids (Jets)
DOI:
https://doi.org/10.1175/JAS4012.1
Page(s):
3328–3339
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Abstract

In a zonally symmetric climatology with a single eddy-driven jet, such as prevails in the Southern Hemisphere summer, the midlatitude variability is dominated by fluctuations of the jet around its mean position, as described by the Southern Hemisphere annular mode (SAM). To study whether this result holds for a zonally asymmetric climatology, the observed variability of the Southern Hemisphere winter is analyzed. The mean state in this case is characterized by relatively weak stationary waves; yet there exist significant zonal variations in the mean strength and meridional structure of the subtropical jet stream.

As in summer, the winter SAM signature is annular in shape and the corresponding wind anomalies are dipolar; but it is associated with two different behaviors of the eddy-driven jet in different longitudinal ranges. Over the Indian Ocean, the SAM is associated primarily with a latitudinal shift of the jet around its mean position. Over the Pacific sector, it is instead characterized by a seesaw in the wind speed between two distinct latitudes, corresponding to the positions of the midlatitude and subtropical jets. Composites of eddy forcing and baroclinicity over both sectors appear consistent with the two different behaviors. As in the zonal-mean case, high-frequency eddies both force and maintain the low-frequency wind anomalies associated with the SAM. The positive feedback by eddies is, however, not local: changes in the eddy forcing are influenced most strongly by zonal wind anomalies located upstream.

Corresponding author address: Dr. Francis Codron, Laboratoire de Météorologie Dynamique, Université Pierre et Marie Curie-Paris/CNRS, 75005 Paris, France. Email: fcodron@lmd.jussieu.fr

This article included in the Jets and Annular Structures in Geophysical Fluids (Jets) special collection.

Abstract

In a zonally symmetric climatology with a single eddy-driven jet, such as prevails in the Southern Hemisphere summer, the midlatitude variability is dominated by fluctuations of the jet around its mean position, as described by the Southern Hemisphere annular mode (SAM). To study whether this result holds for a zonally asymmetric climatology, the observed variability of the Southern Hemisphere winter is analyzed. The mean state in this case is characterized by relatively weak stationary waves; yet there exist significant zonal variations in the mean strength and meridional structure of the subtropical jet stream.

As in summer, the winter SAM signature is annular in shape and the corresponding wind anomalies are dipolar; but it is associated with two different behaviors of the eddy-driven jet in different longitudinal ranges. Over the Indian Ocean, the SAM is associated primarily with a latitudinal shift of the jet around its mean position. Over the Pacific sector, it is instead characterized by a seesaw in the wind speed between two distinct latitudes, corresponding to the positions of the midlatitude and subtropical jets. Composites of eddy forcing and baroclinicity over both sectors appear consistent with the two different behaviors. As in the zonal-mean case, high-frequency eddies both force and maintain the low-frequency wind anomalies associated with the SAM. The positive feedback by eddies is, however, not local: changes in the eddy forcing are influenced most strongly by zonal wind anomalies located upstream.

Corresponding author address: Dr. Francis Codron, Laboratoire de Météorologie Dynamique, Université Pierre et Marie Curie-Paris/CNRS, 75005 Paris, France. Email: fcodron@lmd.jussieu.fr

This article included in the Jets and Annular Structures in Geophysical Fluids (Jets) special collection.

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