Simulations of dynamics and transport during the September 2002 Antarctic major warming

A mechanistic model simulation initialized on 14 September 2002, forced by 100-hPa geopotential heights from Met Office analyses, reproduced the dynamical features of the 2002 Antarctic major warming. The vortex split on ~25 September; recovery after the warming, westward and equatorward tilting vor...

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Main Authors: Manney, Gloria L., Sabutis, Joseph L., Allen, Douglas R., Lahoz, Willian A., Scaife, Adam A., Randall, Cora E., Pawson, Steven, Naujokat, Barbara, Swinbank, Richard
Format: Article in Journal/Newspaper
Language:English
Published: American Meteorological Society 2007
Subjects:
Antartica
warming
winds
Antarctic
Arctic
Tilting
Antarc*
antartic*
Online Access:http://hdl.handle.net/2014/40043
id ftnasajpl:oai:trs.jpl.nasa.gov:2014/40043
record_format openpolar
spelling ftnasajpl:oai:trs.jpl.nasa.gov:2014/40043 2023-05-15T13:31:32+02:00 Simulations of dynamics and transport during the September 2002 Antarctic major warming Manney, Gloria L. Sabutis, Joseph L. Allen, Douglas R. Lahoz, Willian A. Scaife, Adam A. Randall, Cora E. Pawson, Steven Naujokat, Barbara Swinbank, Richard 2007-02-06T23:48:14Z 1717128 bytes application/pdf http://hdl.handle.net/2014/40043 en_US eng American Meteorological Society Journal of the Atmospheric Sciences Volume 62, Issue 3 (March 2005), p. 690-707 03-1492 http://hdl.handle.net/2014/40043 Antartica warming winds Article 2007 ftnasajpl 2021-12-23T13:12:01Z A mechanistic model simulation initialized on 14 September 2002, forced by 100-hPa geopotential heights from Met Office analyses, reproduced the dynamical features of the 2002 Antarctic major warming. The vortex split on ~25 September; recovery after the warming, westward and equatorward tilting vortices, and strong baroclinic zones in temperature associated with a dipole pattern of upward and downward vertical velocities were all captured in the simulation. Model results and analyses show a pattern of strong upward wave propagation throughout the warming, with zonal wind deceleration throughout the stratosphere at high latitudes before the vortex split, continuing in the middle and upper stratosphere and spreading to lower latitudes after the split. Three-dimensional Eliassen–Palm fluxes show the largest upward and poleward wave propagation in the 0°–90°E sector prior to the vortex split (coincident with the location of strongest cyclogenesis at the model’s lower boundary), with an additional region of strong upward propagation developing near 180°–270°E. These characteristics are similar to those of Arctic wave-2 major warmings, except that during this warming, the vortex did not split below ~600 K. The effects of poleward transport and mixing dominate modeled trace gas evolution through most of the mid- to high-latitude stratosphere, with a core region in the lower-stratospheric vortex where enhanced descent dominates and the vortex remains isolated. Strongly tilted vortices led to low-latitude air overlying vortex air, resulting in highly unusual trace gas profiles. Simulations driven with several meteorological datasets reproduced the major warming, but in others, stronger latitudinal gradients at high latitudes at the model boundary resulted in simulations without a complete vortex split in the midstratosphere. Numerous tests indicate very high sensitivity to the boundary fields, especially the wave-2 amplitude. Major warmings occurred for initial fields with stronger winds and larger vortices, but not smaller vortices, consistent with the initiation of wind deceleration by upward-propagating waves near the poleward edge of the region where wave 2 can propagate above the jet core. Thus, given the observed 100-hPa boundary forcing, stratospheric preconditioning is not needed to reproduce a major warming similar to that observed. The anomalously strong forcing in the lower stratosphere can be viewed as the primary direct cause of the major warming. NASA/JPL Article in Journal/Newspaper Antarc* Antarctic antartic* Arctic JPL Technical Report Server Antarctic Arctic Tilting ENVELOPE(-54.065,-54.065,49.700,49.700)
institution Open Polar
collection JPL Technical Report Server
op_collection_id ftnasajpl
language English
topic Antartica
warming
winds
spellingShingle Antartica
warming
winds
Manney, Gloria L.
Sabutis, Joseph L.
Allen, Douglas R.
Lahoz, Willian A.
Scaife, Adam A.
Randall, Cora E.
Pawson, Steven
Naujokat, Barbara
Swinbank, Richard
Simulations of dynamics and transport during the September 2002 Antarctic major warming
topic_facet Antartica
warming
winds
description A mechanistic model simulation initialized on 14 September 2002, forced by 100-hPa geopotential heights from Met Office analyses, reproduced the dynamical features of the 2002 Antarctic major warming. The vortex split on ~25 September; recovery after the warming, westward and equatorward tilting vortices, and strong baroclinic zones in temperature associated with a dipole pattern of upward and downward vertical velocities were all captured in the simulation. Model results and analyses show a pattern of strong upward wave propagation throughout the warming, with zonal wind deceleration throughout the stratosphere at high latitudes before the vortex split, continuing in the middle and upper stratosphere and spreading to lower latitudes after the split. Three-dimensional Eliassen–Palm fluxes show the largest upward and poleward wave propagation in the 0°–90°E sector prior to the vortex split (coincident with the location of strongest cyclogenesis at the model’s lower boundary), with an additional region of strong upward propagation developing near 180°–270°E. These characteristics are similar to those of Arctic wave-2 major warmings, except that during this warming, the vortex did not split below ~600 K. The effects of poleward transport and mixing dominate modeled trace gas evolution through most of the mid- to high-latitude stratosphere, with a core region in the lower-stratospheric vortex where enhanced descent dominates and the vortex remains isolated. Strongly tilted vortices led to low-latitude air overlying vortex air, resulting in highly unusual trace gas profiles. Simulations driven with several meteorological datasets reproduced the major warming, but in others, stronger latitudinal gradients at high latitudes at the model boundary resulted in simulations without a complete vortex split in the midstratosphere. Numerous tests indicate very high sensitivity to the boundary fields, especially the wave-2 amplitude. Major warmings occurred for initial fields with stronger winds and larger vortices, but not smaller vortices, consistent with the initiation of wind deceleration by upward-propagating waves near the poleward edge of the region where wave 2 can propagate above the jet core. Thus, given the observed 100-hPa boundary forcing, stratospheric preconditioning is not needed to reproduce a major warming similar to that observed. The anomalously strong forcing in the lower stratosphere can be viewed as the primary direct cause of the major warming. NASA/JPL
format Article in Journal/Newspaper
author Manney, Gloria L.
Sabutis, Joseph L.
Allen, Douglas R.
Lahoz, Willian A.
Scaife, Adam A.
Randall, Cora E.
Pawson, Steven
Naujokat, Barbara
Swinbank, Richard
author_facet Manney, Gloria L.
Sabutis, Joseph L.
Allen, Douglas R.
Lahoz, Willian A.
Scaife, Adam A.
Randall, Cora E.
Pawson, Steven
Naujokat, Barbara
Swinbank, Richard
author_sort Manney, Gloria L.
title Simulations of dynamics and transport during the September 2002 Antarctic major warming
title_short Simulations of dynamics and transport during the September 2002 Antarctic major warming
title_full Simulations of dynamics and transport during the September 2002 Antarctic major warming
title_fullStr Simulations of dynamics and transport during the September 2002 Antarctic major warming
title_full_unstemmed Simulations of dynamics and transport during the September 2002 Antarctic major warming
title_sort simulations of dynamics and transport during the september 2002 antarctic major warming
publisher American Meteorological Society
publishDate 2007
url http://hdl.handle.net/2014/40043
long_lat ENVELOPE(-54.065,-54.065,49.700,49.700)
geographic Antarctic
Arctic
Tilting
geographic_facet Antarctic
Arctic
Tilting
genre Antarc*
Antarctic
antartic*
Arctic
genre_facet Antarc*
Antarctic
antartic*
Arctic
op_relation Journal of the Atmospheric Sciences Volume 62, Issue 3 (March 2005), p. 690-707
03-1492
http://hdl.handle.net/2014/40043
_version_ 1766018633616588800

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