Abstract
Abstract. A climatology of the occurrence of strong wind shear in the upper troposphere–lower stratosphere (UTLS) is presented, which gives rise to defining a tropopause shear layer (TSL). Strong wind shear in the tropopause region is of interest because it can generate turbulence, which can lead to cross-tropopause mixing. The analysis is based on 10 years of daily northern hemispheric ECMWF ERA5 reanalysis data. The vertical extent of the region analyzed is limited to the altitudes from 1.5 km above the surface up to 25 km, to exclude the planetary boundary layer as well as strong wind shear in higher atmospheric layers like the mesosphere–lower thermosphere. A threshold value of St2=4×10-4s-2 of the squared vertical shear of the horizontal wind is applied, which marks the top end of the distribution of atmospheric wind shear to focus on situations which cannot be sustained by the mean static stability in the troposphere according to linear theory. This subset of the vertical wind shear spectrum is analyzed for its vertical, geographical, and seasonal occurrence frequency distribution. A set of metrics is defined to narrow down the relation to planetary circulation features, as well as indicators for momentum-gradient-sharpening mechanisms. The vertical distribution reveals that strong vertical wind shear above the threshold occurs almost exclusively at tropopause altitudes, within a vertically confined layer of about 1–2 km in extent directly above the local lapse rate tropopause. The TSL emerges as a distinct feature in the tropopause-based 10-year temporal and zonal mean climatology, spanning from the tropics to latitudes around 70∘ N, with average occurrence frequencies on the order of 1 %–10 %. The horizontal distribution of the strong vertical wind shear near the tropopause exhibits distinctly separated regions of occurrence, which are generally associated with jet streams and their seasonality. At midlatitudes, strong wind shear values occur most frequently in regions with an elevated tropopause and at latitudes around 50∘ N, associated with jet streaks within northward-reaching ridges of baroclinic waves. At lower latitudes in the region of the subtropical jet stream, which is mainly apparent over the east Asian continent, the occurrence frequency of strong wind shear near the tropopause reaches maximum values of about 30 % during winter and is tightly linked to the jet stream seasonality. The interannual variability of the occurrence frequency for strong wind shear might furthermore be linked to the variability of the zonal location and strength of the jet. The east-equatorial region features a bi-annual seasonality in the occurrence frequencies of strong vertical wind shear near the tropopause. During the summer months, large areas of the tropopause region over the Indian Ocean are up to 70 % of the time exposed to strong wind shear, which can be attributed to the emergence of the tropical easterly jet. During winter, this occurrence frequency maximum shifts eastward over the maritime continent, where it is exceptionally pronounced during the DJF 2010/11 La Niña phase, as well as quite weak during the El Niño phases of 2009/10, 2014/15, and 2015/16. This agrees with the atmospheric response of the Pacific Walker circulation cell in the El Niño–Southern Oscillation (ENSO) ocean–atmosphere coupling.
Highlights
The distribution of vertical wind shear in the atmosphere is a substantial feature of the dynamic structure because it controls the dynamic stability of the flow
The dynamic stability of the tropopause region is of interest because turbulent mixing in consequence of dynamic instability modifies the trace gas gradients at the tropopause, which in turn can have a significant effect on the radiative budget locally and at the Earth’s surface (Forster and Shine, 1997; Riese et al, 2012)
The analysis presents one way to quantify the link between the occurrence of strong vertical wind shear near the tropopause and the potential temperature of the dynamic tropopause, which can be interpreted as a measure for the excursion of air masses within baroclinic waves in the midlatitudes
Summary
The distribution of vertical wind shear in the atmosphere is a substantial feature of the dynamic structure because it controls the dynamic stability of the flow. Dynamic stability limits the amount of wind shear that is sustainable. The dynamic stability of the tropopause region is of interest because turbulent mixing in consequence of dynamic instability modifies the trace gas gradients at the tropopause, which in turn can have a significant effect on the radiative budget locally and at the Earth’s surface (Forster and Shine, 1997; Riese et al, 2012). Turbulent mixing at the tropopause is a pathway for stratosphere–troposphere exchange (STE; Holton, 1995; Stohl et al, 2003), which is important because of its impact on the chemical budget in the troposphere and the stratosphere
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