Editorial Type:
Article
Article Type:
Research Article

Eddy–Zonal Flow Interactions and the Persistence of the Zonal Index

Edwin P. Gerber Applied Physics and Applied Mathematics, Columbia University, New York, New York

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Geoffrey K. Vallis GFDL, Princeton University, Princeton, New Jersey

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Print Publication:
01 Sep 2007
Collections:
Jets and Annular Structures in Geophysical Fluids (Jets)
DOI:
https://doi.org/10.1175/JAS4006.1
Page(s):
3296–3311
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Abstract

An idealized atmospheric general circulation model is used to investigate the factors controlling the time scale of intraseasonal (10–100 day) variability of the extratropical atmosphere. Persistence on these time scales is found in patterns of variability that characterize meridional vacillations of the extratropical jet. Depending on the degree of asymmetry in the model forcing, patterns take on similar properties to the zonal index, annular modes, and North Atlantic Oscillation. It is found that the time scale of jet meandering is distinct from the obvious internal model time scales, suggesting that interaction between synoptic eddies and the large-scale flow establish a separate, intraseasonal time scale. A mechanism is presented by which eddy heat and momentum transport couple to retard motion of the jet, slowing its meridional variation and thereby extending the persistence of zonal index and annular mode anomalies. The feedback is strong and quite sensitive to model parameters when the model forcing is zonally uniform. However, the time scale of jet variation drops and nearly all sensitivity to parameters is lost when zonal asymmetries, in the form of topography and thermal perturbations that approximate land–sea contrast, are introduced. A diagnostic on the zonal structure of the zonal index provides intuition on the physical nature of the index and annular modes and hints at why zonal asymmetries limit the eddy–mean flow interactions.

Corresponding author address: Edwin P. Gerber, 435 W. 119th Street, Apt. 9M, New York, NY 10027. Email: epg2108@columbia.edu

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

Abstract

An idealized atmospheric general circulation model is used to investigate the factors controlling the time scale of intraseasonal (10–100 day) variability of the extratropical atmosphere. Persistence on these time scales is found in patterns of variability that characterize meridional vacillations of the extratropical jet. Depending on the degree of asymmetry in the model forcing, patterns take on similar properties to the zonal index, annular modes, and North Atlantic Oscillation. It is found that the time scale of jet meandering is distinct from the obvious internal model time scales, suggesting that interaction between synoptic eddies and the large-scale flow establish a separate, intraseasonal time scale. A mechanism is presented by which eddy heat and momentum transport couple to retard motion of the jet, slowing its meridional variation and thereby extending the persistence of zonal index and annular mode anomalies. The feedback is strong and quite sensitive to model parameters when the model forcing is zonally uniform. However, the time scale of jet variation drops and nearly all sensitivity to parameters is lost when zonal asymmetries, in the form of topography and thermal perturbations that approximate land–sea contrast, are introduced. A diagnostic on the zonal structure of the zonal index provides intuition on the physical nature of the index and annular modes and hints at why zonal asymmetries limit the eddy–mean flow interactions.

Corresponding author address: Edwin P. Gerber, 435 W. 119th Street, Apt. 9M, New York, NY 10027. Email: epg2108@columbia.edu

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

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