Noise-induced vortex-splitting stratospheric sudden warmings

Observed oscillations of the Antarctic stratospheric polar vortex often resemble those in Kida's model of an elliptical vortex in a linear background flow. Here, Kida's model is used to investigate the dynamics of “vortex‐splitting” stratospheric sudden warmings (SSWs), such as the Antarct...

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Main Authors:	Esler, JG, Mester, M
Format:	Article in Journal/Newspaper
Language:	English
Published:	Royal Meteorological Society 2019
Subjects:	sudden warmings vortex splits stochastic processes Antarctic The Antarctic Antarc*
Online Access:	https://discovery.ucl.ac.uk/id/eprint/10066234/1/esler_mester_2019.pdf https://discovery.ucl.ac.uk/id/eprint/10066234/

id	ftucl:oai:eprints.ucl.ac.uk.OAI2:10066234
record_format	openpolar
spelling	ftucl:oai:eprints.ucl.ac.uk.OAI2:10066234 2023-12-24T10:11:31+01:00 Noise-induced vortex-splitting stratospheric sudden warmings Esler, JG Mester, M 2019-01 text https://discovery.ucl.ac.uk/id/eprint/10066234/1/esler_mester_2019.pdf https://discovery.ucl.ac.uk/id/eprint/10066234/ eng eng Royal Meteorological Society https://discovery.ucl.ac.uk/id/eprint/10066234/1/esler_mester_2019.pdf https://discovery.ucl.ac.uk/id/eprint/10066234/ open Quarterly Journal of the Royal Meteorological Society , 145 (719) pp. 476-494. (2019) sudden warmings vortex splits stochastic processes Article 2019 ftucl 2023-11-27T13:07:38Z Observed oscillations of the Antarctic stratospheric polar vortex often resemble those in Kida's model of an elliptical vortex in a linear background flow. Here, Kida's model is used to investigate the dynamics of “vortex‐splitting” stratospheric sudden warmings (SSWs), such as the Antarctic event of 2002. SSWs are identified with a bifurcation in the periodic orbits of the model. The influence of “tropospheric macroturbulence” on the vortex is modelled by allowing the linear background forcing flow to be driven by a random process, with a finite decorrelation time (an Ornstein–Uhlenbeck process). It is shown that this stochasticity generates a random walk across the state‐space of periodic orbits, which will eventually lead to a bifurcation point after which an SSW will occur. In certain asymptotic limits, the expected time before an SSW occurs can be found by solving a “first passage time” problem for a stochastic differential equation, allowing the dependence of the expected time to an SSW on the model parameters to be elucidated. Results are verified using both Kida's model and single‐layer quasi‐geostrophic simulations. The results point towards a “noise‐memory” paradigm of the winter stratosphere, according to which the forcing history determines whether the vortex is quiescent, whether it undergoes large amplitude nonlinear oscillations or, in extreme cases, whether the vortex will eventually split. Article in Journal/Newspaper Antarc* Antarctic University College London: UCL Discovery Antarctic The Antarctic
institution	Open Polar
collection	University College London: UCL Discovery
op_collection_id	ftucl
language	English
topic	sudden warmings vortex splits stochastic processes
spellingShingle	sudden warmings vortex splits stochastic processes Esler, JG Mester, M Noise-induced vortex-splitting stratospheric sudden warmings
topic_facet	sudden warmings vortex splits stochastic processes
description	Observed oscillations of the Antarctic stratospheric polar vortex often resemble those in Kida's model of an elliptical vortex in a linear background flow. Here, Kida's model is used to investigate the dynamics of “vortex‐splitting” stratospheric sudden warmings (SSWs), such as the Antarctic event of 2002. SSWs are identified with a bifurcation in the periodic orbits of the model. The influence of “tropospheric macroturbulence” on the vortex is modelled by allowing the linear background forcing flow to be driven by a random process, with a finite decorrelation time (an Ornstein–Uhlenbeck process). It is shown that this stochasticity generates a random walk across the state‐space of periodic orbits, which will eventually lead to a bifurcation point after which an SSW will occur. In certain asymptotic limits, the expected time before an SSW occurs can be found by solving a “first passage time” problem for a stochastic differential equation, allowing the dependence of the expected time to an SSW on the model parameters to be elucidated. Results are verified using both Kida's model and single‐layer quasi‐geostrophic simulations. The results point towards a “noise‐memory” paradigm of the winter stratosphere, according to which the forcing history determines whether the vortex is quiescent, whether it undergoes large amplitude nonlinear oscillations or, in extreme cases, whether the vortex will eventually split.
format	Article in Journal/Newspaper
author	Esler, JG Mester, M
author_facet	Esler, JG Mester, M
author_sort	Esler, JG
title	Noise-induced vortex-splitting stratospheric sudden warmings
title_short	Noise-induced vortex-splitting stratospheric sudden warmings
title_full	Noise-induced vortex-splitting stratospheric sudden warmings
title_fullStr	Noise-induced vortex-splitting stratospheric sudden warmings
title_full_unstemmed	Noise-induced vortex-splitting stratospheric sudden warmings
title_sort	noise-induced vortex-splitting stratospheric sudden warmings
publisher	Royal Meteorological Society
publishDate	2019
url	https://discovery.ucl.ac.uk/id/eprint/10066234/1/esler_mester_2019.pdf https://discovery.ucl.ac.uk/id/eprint/10066234/
geographic	Antarctic The Antarctic
geographic_facet	Antarctic The Antarctic
genre	Antarc* Antarctic
genre_facet	Antarc* Antarctic
op_source	Quarterly Journal of the Royal Meteorological Society , 145 (719) pp. 476-494. (2019)
op_relation	https://discovery.ucl.ac.uk/id/eprint/10066234/1/esler_mester_2019.pdf https://discovery.ucl.ac.uk/id/eprint/10066234/
op_rights	open
_version_	1786166162636144640

Noise-induced vortex-splitting stratospheric sudden warmings

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