Abstract
Abstract. The stratopause is by definition the transition between the stratosphere and mesosphere. During winter the circulation at mid-latitudes and high latitudes in the stratosphere is mainly driven by quasi-stationary planetary waves (PWs), while the circulation in the mesosphere is mainly driven by gravity waves (GWs). The question arises of whether PWs or GWs dominate the variability of the stratopause. The most famous and dramatic variability of the middle atmosphere is a sudden stratospheric warming (SSW) generated by PWs interacting with the polar vortex. A similar phenomenon but smaller in magnitude and more regional is stratopause temperature enhancements (STEs) initially observed by local measurements and generated by breaking PWs. Thus it seems that PWs dominate the variability of the stratopause. In this study we want to quantify to which extent quasi-stationary PWs contribute to the stratopause variability. To do that we combine local lidar observations at Kühlungsborn (54∘ N, 11∘ E) and Andenes (69∘ N, 16∘ E) with global MERRA-2 reanalysis data bringing the local variability of the stratopause into the global context. Therefore we compare the temperature time series at Kühlungsborn and Andenes at 2 hPa, the altitude where STEs maximize, with characteristics (amplitude and phase) of PWs with wave numbers 1, 2 and 3. We found that for Kühlungsborn and Andenes 98 % of the local day-to-day variability of the stratopause can be explained by the variability of PWs with wave number 1, 2 and 3. Thus, the winter stratopause day-to-day variability is highly dominated by the variability of PWs.
Highlights
Upper stratosphere–lower mesosphere (USLM) temperatures are a sensitive indicator for climate change (Rind et al, 1998)
Before we compare the temporal evolution of local stratopause temperatures with the temporal evolution of planetary waves (PWs) at the same altitude and latitude, we study the vertical profile of stratopause temperature enhancements (STEs) using lidar data and compare the results with profiles of MERRA-2 reanalysis data
We combine local lidar measurements at midlatitudes and high latitudes with global MERRA-2 reanalysis data to bring the local variability into the global context
Summary
Upper stratosphere–lower mesosphere (USLM) temperatures are a sensitive indicator for climate change (Rind et al, 1998). The polar vortex is disturbed in the Northern Hemisphere by planetary Rossby waves (PWs) generated in the troposphere and propagating upward under westerly wind conditions into the middle atmosphere (Charney and Drazin, 1961; Matsuno, 1970). The strongest PWs that occur in the winter middle atmosphere are quasi-stationary PWs (Matsuno, 1970) When those waves break they deposit their momentum in the middle atmosphere (McIntyre and Palmer, 1983) and driving especially the stratosphere away from its radiative equilibrium by generating a mean meridional circulation from Equator to pole with downward motion at the pole which adiabatically warms the polar stratosphere (e.g. Hitchman et al, 1989; Plumb, 2002; Manney et al, 2008). In the mesosphere the main driver of the circulation is gravity waves (GWs) by implementing a mean meridional circulation from the summer to the winter pole with accompanied upward motion in summer and downward motion in winter resulting in a warmer winter meso-
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