Weakening of the Teleconnection From El Niño–Southern Oscillation to the Arctic Stratosphere Over the Past Few Decades: What Can Be Learned From Subseasonal Forecast Models?

Garfinkel, Chaim I.; Schwartz, Chen; Butler, Amy H.; Domeisen, Daniela I. V.; Son, Seok‐Woo; White, Ian

doi:10.1029/2018jd029961

Cited by 25 publications

(34 citation statements)

References 79 publications

(147 reference statements)

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“…4c and d. Specifically, ozone anomalies are usually accompanied by anomalies in the Arctic vortex ( Fig. 4a and b), and previous work has shown that spring Arctic vortex anomalies independent of ozone can influence surface conditions (Black and McDaniel, 2007;Ayarzagüena and Serrano, 2009;Hardiman et al, 2011). We now demonstrate that vortex anomalies are associated with polar cap PS anomalies in the CCMI models as well and then try to isolate statistically the relative importance of ASO.…”

Section: Effect Of Arctic Stratospheric Ozone (Aso) On Polar Surface supporting

confidence: 63%

response to reviewer 2

Harari¹

2019

Preprint

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The Northern Hemisphere and tropical circulation response to interannual variability in Arctic stratospheric ozone is analyzed in a set of the latest model simulations archived for the Chemistry-Climate Model Initiative (CCMI) project. All models simulate a connection between ozone variability and temperature/geopotential height in the lower stratosphere similar to that observed. A connection between Arctic ozone variability and polar cap surface air pressure is also found, but additional statistical analysis suggests that it is mediated by the dynamical variability that typically drives the anomalous ozone concentrations. While the CCMI models also show a connection between Arctic stratospheric ozone and the El Niño-Southern Oscillation (ENSO), with Arctic stratospheric ozone variability leading to ENSO variability 1 to 2 years later, this relationship in the models is much weaker than observed and is likely related to ENSO autocorrelation rather than any forced response to ozone. Overall, Arctic stratospheric ozone is related to lower stratospheric variability. Arctic stratospheric ozone may also influence the surface in both polar and tropical latitudes, though ozone is likely not the proximate cause of these impacts and these impacts can be masked by internal variability if data are only available for ∼ 40 years.Published by Copernicus Publications on behalf of the European Geosciences Union.

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Section: Effect Of Arctic Stratospheric Ozone (Aso) On Polar Surface supporting

confidence: 63%

response to reviewer 2

Harari¹

2019

Preprint

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“…This brief analysis suggests some relationship, but given the short record, it is not clear whether this interannual relationship might be dominated by ENSO teleconnections to the stratosphere (Domeisen et al, ) or is a sampling artifact. Note that during the 1981–2016 period, more SSWs occurred during La Niña than El Niño (Garfinkel et al, ). Of the nine El Niño winters that were followed by early FWs, only two had midwinter SSWs.…”

Section: Resultsmentioning

confidence: 99%

Predictability of Northern Hemisphere Final Stratospheric Warmings and Their Surface Impacts

Butler

Charlton‐Perez

Domeisen

et al. 2019

Geophysical Research Letters

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Each spring, the climatological westerly winds of the Northern Hemisphere (NH) stratospheric polar vortex turn easterly as the stratospheric equator‐to‐pole temperature gradient relaxes. The timing of this event is dictated both by the annual return of sunlight to the pole and by dynamical influences from the troposphere. Here we consider the predictability of NH final stratospheric warmings in multimodel hindcasts from the Subseasonal to Seasonal project database. We evaluate how well the Subseasonal to Seasonal prediction systems perform in capturing the timing of final warmings. We compare the predictability of early warmings (which are more strongly driven by wave forcing) and late warmings and find that late warmings are more skillfully predicted at longer lead times. Finally, we find significantly increased predictive skill of NH near‐surface temperature anomalies at Weeks 3–4 lead times following only early final warmings.

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“…The fully coupled approach of Calvo et al (2015) allows consistency between the evolving ozone distributions and dynamical conditions among other differences in the model configuration, which may explain the differences between their conclusions and those of studies prescribing ozone concentrations. However, there is some ambiguity in the approach of Calvo et al (2015) as to whether the surface anomalies are due exclusively to chemical depletion of ozone: ozone anomalies are usually accompanied by anomalies in the Arctic vortex (i.e., early or delayed breakup of the Arctic vortex for high ozone or low ozone respectively, Hurwitz et al, 2011), and vortex anomalies independent of ozone have been shown to influence surface conditions (Black and McDaniel, 2007;Ayarzagüena and Serrano, 2009;Hardiman et al, 2011). Hence the degree to which the surface anomalies found by Calvo et al (2015) are related to chemical ozone depletion rather than the altered dynamical state of the vortex which also affects ozone concentrations is ambiguous.…”

Section: Introductionmentioning

confidence: 99%

“…The standard deviation in CHASER is much less than that observed, and hence this model was excluded from further analysis. et al (2017) (e.g., Black and McDaniel, 2007;Ayarzagüena and Serrano, 2009;Hardiman et al, 2011), and it is not clear whether the surface response is due to the dynamical impact from the final warming as opposed to the radiative impact of the ozone anomaly that typically accompanies a final warming. Finally, Xie et al (2016) suggest that ASO anomalies influence sea level pressure anomalies over the North Pacific, which in turn modulates subtropical sea surface temperatures.…”

Section: Introductionmentioning

confidence: 99%

Influence of Arctic stratospheric ozone on surface climate in CCMI models

et al. 2019

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Abstract. The Northern Hemisphere and tropical circulation response to interannual variability in Arctic stratospheric ozone is analyzed in a set of the latest model simulations archived for the Chemistry-Climate Model Initiative (CCMI) project. All models simulate a connection between ozone variability and temperature/geopotential height in the lower stratosphere similar to that observed. A connection between Arctic ozone variability and polar cap surface air pressure is also found, but additional statistical analysis suggests that it is mediated by the dynamical variability that typically drives the anomalous ozone concentrations. While the CCMI models also show a connection between Arctic stratospheric ozone and the El Niño–Southern Oscillation (ENSO), with Arctic stratospheric ozone variability leading to ENSO variability 1 to 2 years later, this relationship in the models is much weaker than observed and is likely related to ENSO autocorrelation rather than any forced response to ozone. Overall, Arctic stratospheric ozone is related to lower stratospheric variability. Arctic stratospheric ozone may also influence the surface in both polar and tropical latitudes, though ozone is likely not the proximate cause of these impacts and these impacts can be masked by internal variability if data are only available for ∼40 years.

show abstract

Weakening of the Teleconnection From El Niño–Southern Oscillation to the Arctic Stratosphere Over the Past Few Decades: What Can Be Learned From Subseasonal Forecast Models?

Cited by 25 publications

References 79 publications

response to reviewer 2

response to reviewer 2

Predictability of Northern Hemisphere Final Stratospheric Warmings and Their Surface Impacts

Influence of Arctic stratospheric ozone on surface climate in CCMI models

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