Arctic Oscillation regime behavior in an idealized atmospheric circulation model as a result of almost-intransitivity

A quasi-geostrophic, hemispheric three-level atmospheric modelwith horizontal T21 resolution is driven by Northern Hemisphere's T21topography, whereas its thermal and surface forcingare determined by an automated, iterative tuning procedure.The zonal parts of the forcings are tuned toproduce a...

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Main Authors: Sempf, M., Dethloff, Klaus, Handorf, Dörthe, Kurgansky, Michael
Format: Conference Object
Language:unknown
Published: 2005
Subjects:
Arctic
Online Access:https://epic.awi.de/id/eprint/14037/
https://hdl.handle.net/10013/epic.24386
id ftawi:oai:epic.awi.de:14037
record_format openpolar
spelling ftawi:oai:epic.awi.de:14037 2023-09-05T13:15:53+02:00 Arctic Oscillation regime behavior in an idealized atmospheric circulation model as a result of almost-intransitivity Sempf, M. Dethloff, Klaus Handorf, Dörthe Kurgansky, Michael 2005 https://epic.awi.de/id/eprint/14037/ https://hdl.handle.net/10013/epic.24386 unknown Sempf, M. , Dethloff, K. , Handorf, D. orcid:0000-0002-3305-6882 and Kurgansky, M. (2005) Arctic Oscillation regime behavior in an idealized atmospheric circulation model as a result of almost-intransitivity , Scientific Assembly of the International Association of Meteorology and Atmospheric Sciences, 2-11 August, Beijing, China. . hdl:10013/epic.24386 EPIC3Scientific Assembly of the International Association of Meteorology and Atmospheric Sciences, 2-11 August, Beijing, China. Conference notRev 2005 ftawi 2023-08-22T19:50:57Z A quasi-geostrophic, hemispheric three-level atmospheric modelwith horizontal T21 resolution is driven by Northern Hemisphere's T21topography, whereas its thermal and surface forcingare determined by an automated, iterative tuning procedure.The zonal parts of the forcings are tuned toproduce a realistic zonal wind profile for northern winter, while non-zonalthermal forcings are adjusted to obtain time-averaged non-zonal diabaticheating fields equal to wintertime observations. The perpetual wintermodel simulation reproduces observed wintertime climatology and patterns oflow-frequency variability with accuracy. The model exhibits two significantcirculation regimes which correspond to the positive and negative phase ofthe Arctic Oscillation (AO), respectively.Steady solutions of the model equations have been determined, but they do notcoincide with the regime centroids. They are even far outside of the system'sattractor and therefore do not directly influence the model's dynamics. Butan explanationof the dynamical structures underlying the model's regime behaviour issuggested by the results of a series of model experiments, in which thetuning procedure is repeated using lower values of surface friction.The weaker surface friction is, the moredistant and pronounced the two AO regimes become, indicated by increasinggeopotential standard deviation at polar latitudes and alsoby the AO index distribution, the bimodality of which is becoming more andmore extreme. The regime persistence, but also themodel's sensitivity with respect to forcing changes dramatically increase.Due to this sensitivity, the tuning procedure fails to reproduce the observedzonal climate if the strength of the surface friction is below some criticalvalue. Rather, the model's climate flips between the two extreme AO phasesfrom one tuning iteration to another, but still allows for rare jumpsto the other regime, respectively.Based on these results, the two regimes observed in the control simulationare interpreted as a feature of the attractor's ... Conference Object Arctic Arctic Alfred Wegener Institute for Polar- and Marine Research (AWI): ePIC (electronic Publication Information Center) Arctic
institution Open Polar
collection Alfred Wegener Institute for Polar- and Marine Research (AWI): ePIC (electronic Publication Information Center)
op_collection_id ftawi
language unknown
description A quasi-geostrophic, hemispheric three-level atmospheric modelwith horizontal T21 resolution is driven by Northern Hemisphere's T21topography, whereas its thermal and surface forcingare determined by an automated, iterative tuning procedure.The zonal parts of the forcings are tuned toproduce a realistic zonal wind profile for northern winter, while non-zonalthermal forcings are adjusted to obtain time-averaged non-zonal diabaticheating fields equal to wintertime observations. The perpetual wintermodel simulation reproduces observed wintertime climatology and patterns oflow-frequency variability with accuracy. The model exhibits two significantcirculation regimes which correspond to the positive and negative phase ofthe Arctic Oscillation (AO), respectively.Steady solutions of the model equations have been determined, but they do notcoincide with the regime centroids. They are even far outside of the system'sattractor and therefore do not directly influence the model's dynamics. Butan explanationof the dynamical structures underlying the model's regime behaviour issuggested by the results of a series of model experiments, in which thetuning procedure is repeated using lower values of surface friction.The weaker surface friction is, the moredistant and pronounced the two AO regimes become, indicated by increasinggeopotential standard deviation at polar latitudes and alsoby the AO index distribution, the bimodality of which is becoming more andmore extreme. The regime persistence, but also themodel's sensitivity with respect to forcing changes dramatically increase.Due to this sensitivity, the tuning procedure fails to reproduce the observedzonal climate if the strength of the surface friction is below some criticalvalue. Rather, the model's climate flips between the two extreme AO phasesfrom one tuning iteration to another, but still allows for rare jumpsto the other regime, respectively.Based on these results, the two regimes observed in the control simulationare interpreted as a feature of the attractor's ...
format Conference Object
author Sempf, M.
Dethloff, Klaus
Handorf, Dörthe
Kurgansky, Michael
spellingShingle Sempf, M.
Dethloff, Klaus
Handorf, Dörthe
Kurgansky, Michael
Arctic Oscillation regime behavior in an idealized atmospheric circulation model as a result of almost-intransitivity
author_facet Sempf, M.
Dethloff, Klaus
Handorf, Dörthe
Kurgansky, Michael
author_sort Sempf, M.
title Arctic Oscillation regime behavior in an idealized atmospheric circulation model as a result of almost-intransitivity
title_short Arctic Oscillation regime behavior in an idealized atmospheric circulation model as a result of almost-intransitivity
title_full Arctic Oscillation regime behavior in an idealized atmospheric circulation model as a result of almost-intransitivity
title_fullStr Arctic Oscillation regime behavior in an idealized atmospheric circulation model as a result of almost-intransitivity
title_full_unstemmed Arctic Oscillation regime behavior in an idealized atmospheric circulation model as a result of almost-intransitivity
title_sort arctic oscillation regime behavior in an idealized atmospheric circulation model as a result of almost-intransitivity
publishDate 2005
url https://epic.awi.de/id/eprint/14037/
https://hdl.handle.net/10013/epic.24386
geographic Arctic
geographic_facet Arctic
genre Arctic
Arctic
genre_facet Arctic
Arctic
op_source EPIC3Scientific Assembly of the International Association of Meteorology and Atmospheric Sciences, 2-11 August, Beijing, China.
op_relation Sempf, M. , Dethloff, K. , Handorf, D. orcid:0000-0002-3305-6882 and Kurgansky, M. (2005) Arctic Oscillation regime behavior in an idealized atmospheric circulation model as a result of almost-intransitivity , Scientific Assembly of the International Association of Meteorology and Atmospheric Sciences, 2-11 August, Beijing, China. . hdl:10013/epic.24386
_version_ 1776197693750640640

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