Elliptical diagnostics of stratospheric polar vortices

Waugh, Darryn W.

doi:10.1002/qj.49712354213

Cited by 91 publications

(52 citation statements)

References 39 publications

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“…The use of 2-D moment analysis to study the polar vortex was first discussed by Waugh [1997] and Waugh and Randel [1999] and has been recently revisited by Mitchell et al [2011]. The method of S13 describes the geometry of the polar vortex using 10 hPa geopotential height.…”

Section: Methodsmentioning

confidence: 99%

Do split and displacement sudden stratospheric warmings have different annular mode signatures?

Maycock

Hitchcock

2015

Geophysical Research Letters

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Sudden stratospheric warmings (SSWs) contribute to intraseasonal tropospheric forecasting skill due to their surface impacts. Recent studies suggest these impacts depend upon whether the polar vortex splits or is displaced during the SSW. We analyze the annular mode signatures of SSWs in a 1000 year IPSL‐CM5A‐LR simulation. Although small differences in the mean surface Northern Annular Mode (NAM) index following splits and displacements are found, the sign is not consistent for two independent SSW algorithms, and over 50 events are required to distinguish the responses. We use the wintertime correlation between extratropical lower stratospheric wind anomalies and the surface NAM index as a metric for two‐way stratosphere‐troposphere coupling and find that the differences between splits and displacements, and between classification methodologies, can be simply understood in terms of their mean stratospheric wind anomalies. Predictability studies should therefore focus on understanding the factors that determine the persistence of these anomalies following SSWs.

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Section: Methodsmentioning

confidence: 99%

Do split and displacement sudden stratospheric warmings have different annular mode signatures?

Maycock

Hitchcock

2015

Geophysical Research Letters

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“…2.3), which may enable classification of split-type SSWs according to the CP07 definition, in which the edges of the vortex are identified by the location of the maximum absolute vorticity gradient. We also provide potential vorticity (PV) interpolated onto isentropic surfaces, and geopotential heights at 10 hPa, both of which can be used to assess vortex moment diagnostics and determine the SSW type (Mitchell et al, 2011;Seviour et al, 2013;Waugh, 1997). We note that the vortex moment diagnostics detect some different dates of SSWs compared to CP07 (and these events are not included in the Compendium), but the provided data would allow classification of the included events.…”

Section: Event Selectionmentioning

confidence: 99%

A sudden stratospheric warming compendium

Butler

Sjoberg

Seidel

et al. 2017

Earth Syst. Sci. Data

328

316

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Abstract. Major, sudden midwinter stratospheric warmings (SSWs) are large and rapid temperature increases in the winter polar stratosphere are associated with a complete reversal of the climatological westerly winds (i.e., the polar vortex). These extreme events can have substantial impacts on winter surface climate, including increased frequency of cold air outbreaks over North America and Eurasia and anomalous warming over Greenland and eastern Canada. Here we present a SSW Compendium (SSWC), a new database that documents the evolution of the stratosphere, troposphere, and surface conditions 60 days prior to and after SSWs for the period 1958-2014. The SSWC comprises data from six different reanalysis products: MERRA2

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“…[37] The climatologies of the polar vortices in the various runs are compared using elliptical diagnostics [Waugh, 1997]. This method enables construction of a single ellipse representing the mean state of the polar vortex over an arbitrary averaging period.…”

Section: Vortex Climatologymentioning

confidence: 99%

Middle‐atmospheric response to a future increase in humidity arising from increased methane abundance

MacKenzie

Harwood

2004

J. Geophys. Res.

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[1] The response of the middle atmosphere to an increase in humidity arising from a possible future increase in CH 4 is examined in a general circulation model with interactive H 2 O and O 3 . A chemical parameterization allows the middle-atmospheric H 2 O change to evolve naturally from an imposed change in tropospheric CH 4 . First, a simulation of the year 2060 using postulated loadings of the radiatively active gases is compared with a control simulation of the present-day atmosphere. Then, the particular contribution of the CH 4 (and hence H 2 O) change to the observed difference is isolated by repeating the 2060 simulation without the projected CH 4 change. Under the Intergovernmental Panel on Climate Change Special Report on Emission Scenarios (SRES) B2 scenario, the middle atmosphere in 2060 cools by up to $5 K relative to 1995, with the CH 4 -derived increase in H 2 O accounting for $10% of the change. The cooling is accompanied by a strengthened general circulation, intensified dynamic heating rates, and a reduction in the mean age of middle-atmospheric air. The component of the circulation change attributable solely to the H 2 O change differs somewhat from the net response: The H 2 O change causes a greater increase in the descent rate in the north than in the south, ages the stratospheric air, and has a distinct effect on age/N 2 O correlations. Around 20% of the increased prevalence of polar stratospheric clouds (PSCs) in 2060 is due to the microphysical effect of the extra H 2 O, with the remainder attributable to the reduced vortex temperatures. Although the PSC increase facilitates release of reactive chlorine, this positive impact on chemical O 3 destruction is outweighed by the negative impact of the reduced total chlorine in 2060. Nonetheless, the H 2 O increase does make the 2060 Arctic O 3 loss $15% greater than it would otherwise be.

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Elliptical diagnostics of stratospheric polar vortices

Cited by 91 publications

References 39 publications

Do split and displacement sudden stratospheric warmings have different annular mode signatures?

Do split and displacement sudden stratospheric warmings have different annular mode signatures?

A sudden stratospheric warming compendium

Middle‐atmospheric response to a future increase in humidity arising from increased methane abundance

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