Effects of meridional sea surface temperature changes on stratospheric temperature and circulation

Hu, Dingzhu; Tian, Wenshou; Xie, Fei; Shu, Juan; Dhomse, Sandip

doi:10.1007/s00376-013-3152-6

Cited by 56 publications

(66 citation statements)

References 44 publications

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“…It is noteworthy that warm (cold) SST anomalies are generally thought to increase (suppress) planetary wave activity via strengthening (weakening) convection (Xie et al, 2008;Shu et al, 2011;Hu et al, 2014). However, this study shows that warm (cold) SST anomalies over the marginal seas of East Asia suppress (increase) planetary wave activity in the southern high-latitude stratosphere.…”

Section: S3contrasting

confidence: 43%

The relationship between lower-stratospheric ozone at southern high latitudes and sea surface temperature in the East Asian marginal seas in austral spring

Tian

Xie

et al. 2017

Atmos. Chem. Phys.

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Abstract. Using satellite observations, reanalysis data, and model simulations, this study investigates the effect of sea surface temperature (SST) on interannual variations of lower-stratospheric ozone at southern high latitudes in austral spring. It is found that the SST variations across the East Asian marginal seas (5 • S-35 • N, 100-140 • E) rather than the tropical eastern Pacific Ocean, where ENSO occurs, have the most significant correlation with the southern high-latitude lower-stratospheric ozone changes in austral spring. Further analysis reveals that planetary waves originating over the marginal seas in austral spring can propagate towards southern middle to high latitudes via teleconnection pathway. The anomalous propagation and dissipation of ultra-long Rossby waves in the stratosphere strengthen/cool (weaken/warm) the southern polar vortex, which produces more (less) active chlorine and enhances (suppresses) ozone depletion in the southern high-latitude stratosphere on one the hand and impedes (favors) the transport of ozone from the southern middle-latitude stratosphere to high latitudes on the other. The model simulations also reveal that approximately 17 % of the decreasing trend in the southern highlatitude lower-stratospheric ozone observed over the past 5 decades may be associated with the increasing trend in SST over the East Asian marginal seas.

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Section: S3contrasting

confidence: 43%

The relationship between lower-stratospheric ozone at southern high latitudes and sea surface temperature in the East Asian marginal seas in austral spring

Tian

Xie

et al. 2017

Atmos. Chem. Phys.

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“…Previous studies have shown that an increase in GHGs leads to a warmer troposphere and a cooler stratosphere via its direct radiational effects and indirect SST effects, which in turn affects the wave propagation from the troposphere into the stratosphere and further strengthens the BDC [5]. Stratospheric ozone has important impacts on the BDC Advances in Meteorology through the radiational and chemical processes [2,45,46].…”

Section: Effects Of Ghgs and The Stratospheric Ozone On The Bdcmentioning

confidence: 99%

“…During 2001-2050, the warmed Antarctic stratosphere may lead to a weakened latitudinal temperature gradient ( Figure 6(c)), which, following the thermal wind relationship, would be accompanied by a weakened westerly wind in the Antarctic stratosphere and an equatorward displacement of the southern subtropical jet (Figure 6(d)). The above-mentioned zonal wind changes imply a change in refractive index [10], which in turn can influence the propagation of planetary waves from the troposphere to the stratosphere [5,43]. As the eddy heat flux (V ) can well represent the vertical flux of wave activity well [44], we examine the trends of eddy heat flux in DJF during the two periods (Figure 7).…”

Section: Planetary-wave Flux Trendsmentioning

confidence: 99%

“…Changes in the BDC can modulate the global radiation balance by affecting the meridional distribution of the natural and anthropogenic tracer gases in the stratosphere, further influencing climate and environmental changes at the global scale [2][3][4][5][6][7]. For example, ozone-depleting substances that follow the BDC are transported into the polar stratosphere where they influence the concentration of ozone [8][9][10][11][12].…”

Section: Introductionmentioning

confidence: 99%

“…Since the BDC has important impacts on the climate of the troposphere and stratosphere [2][3][4][5][6], it is also important to be able to predict its trend under the expected climatic conditions of the future. As mentioned above, an increase in the concentration of CO 2 results in an accelerated BDC [2,3,[18][19][20], and stratospheric ozone depletion can also lead to a strengthening of downwelling in the high-latitude stratosphere [2,25].…”

Section: Introductionmentioning

confidence: 99%

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Brewer–Dobson Circulation: Recent-Past and Near-Future Trends Simulated by Chemistry-Climate Models

Guo

Wang

et al. 2017

Advances in Meteorology

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Based on data from 16 chemistry-climate models (CCMs) and separate experimental results using a state-of-the-art CCM, the trends in the Brewer-Dobson circulation (BDC) during the second half of the 20th century and the first half of the 21st century are examined. From the ensemble mean of the CCMs, the BDC exhibits strengthening trends in both the 20th and 21st centuries; however, the acceleration rates of tropical upwelling and southern downwelling during 2001-2050 are smaller than those during 1960-2000, while the acceleration rate of the northern downward branch of the BDC during 2001-2050 is slightly larger than that during 1960-2000. The differences in the extratropical downwelling trends between the two periods are closely related to changes in planetary-wave propagation into the stratosphere caused by the combined effects of increases in the concentrations of greenhouse gases (GHGs) and changes in stratospheric ozone. Model simulations demonstrate that the response of southern downwelling to stratospheric ozone depletion is larger than that to the increase in GHGs, but that the latter plays a more important role in the strengthening of northern downwelling. This result suggests that, under the expected future climate, northern downwelling will play a more important role in balancing tropical upwelling.

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Impacts of stratospheric ozone depletion and recovery on wave propagation in the boreal winter stratosphere

Tian

Xie

et al. 2015

JGR Atmospheres

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This paper uses a state-of-the-art general circulation model to study the impacts of the stratospheric ozone depletion from 1980 to 2000 and the expected partial ozone recovery from 2000 to 2020 on the propagation of planetary waves in December, January, and February. In the Southern Hemisphere (SH), the stratospheric ozone depletion leads to a cooler and stronger Antarctic stratosphere, while the stratospheric ozone recovery has the opposite effects. In the Northern Hemisphere (NH), the impacts of the stratospheric ozone depletion on polar stratospheric temperature are not opposite to that of the stratospheric ozone recovery; i.e., the stratospheric ozone depletion causes a weak cooling and the stratospheric ozone recovery causes a statistically significant cooling. The stratospheric ozone depletion leads to a weakening of the Arctic polar vortex, while the stratospheric ozone recovery leads to a strengthening of the Arctic polar vortex. The cooling of the Arctic polar vortex is found to be dynamically induced via modulating the planetary wave activity by stratospheric ozone increases. Particularly interesting is that stratospheric ozone changes have opposite effects on the stationary and transient wave fluxes in the NH stratosphere. The analysis of the wave refractive index and Eliassen-Palm flux in the NH indicates (1) that the wave refraction in the stratosphere cannot fully explain wave flux changes in the Arctic stratosphere and (2) that stratospheric ozone changes can cause changes in wave propagation in the northern midlatitude troposphere which in turn affect wave fluxes in the NH stratosphere. In the SH, the radiative cooling (warming) caused by stratospheric ozone depletion (recovery) produces a larger (smaller) meridional temperature gradient in the midlatitude upper troposphere, accompanied by larger (smaller) zonal wind vertical shear and larger (smaller) vertical gradients of buoyancy frequency. Hence, there are more (fewer) transient waves propagating into the stratosphere. The dynamical warming (cooling) caused by stratospheric ozone decreases (increases) partly offsets their radiative cooling (warming).

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Effects of meridional sea surface temperature changes on stratospheric temperature and circulation

Cited by 56 publications

References 44 publications

The relationship between lower-stratospheric ozone at southern high latitudes and sea surface temperature in the East Asian marginal seas in austral spring

The relationship between lower-stratospheric ozone at southern high latitudes and sea surface temperature in the East Asian marginal seas in austral spring

Brewer–Dobson Circulation: Recent-Past and Near-Future Trends Simulated by Chemistry-Climate Models

Impacts of stratospheric ozone depletion and recovery on wave propagation in the boreal winter stratosphere

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