Abstract
AbstractWe analyze the potential vorticity of Saturn's polar regions, as it is a fundamental dynamical tracer that enables us to improve our understanding of the dynamics of these regions and their seasonal variability. In particular, we present zonally averaged quasi‐geostrophic potential vorticity maps between 68° planetographic latitude and the poles at altitudes between 500 and 1 mbar for three different epochs: (i) June 2013 (early northern summer) for the north polar region, (ii) December 2008 (late northern winter) for both polar regions, and (iii) October 2006 (southern summer) for the south, computed using temperature profiles retrieved from Cassini Composite Infrared Spectrometer data and wind profiles obtained from Cassini's Imaging Science Subsystem. The results show that quasi‐geostrophic potential vorticity maps are very similar at all the studied epochs, showing positive vorticities at the north and negative at the south, indicative of the dominance of the Coriolis parameter 2Ωsinϕ at all latitudes, except near the pole. The meridional gradients of the quasi‐geostrophic potential vorticity show that dynamical instabilities, mainly due to the barotropic term, could develop at the flanks of the Hexagon at 78°N, the jet at 73.9°S, and on the equatorward flank of both polar jets. There are no differences in potential vorticity gradients between the two hemispheres that could explain why a hexagon forms in the north and not in the south. No seasonal variability of the potential vorticity and its meridional gradient has been found, despite significant changes in the atmospheric temperatures over time.
Highlights
Saturn's rotation axis is tilted at an angle of 26.7° relative to its orbital plane, causing substantial seasonal variations of insolation over a 29.5‐year cycle
We find that the quasi‐geostrophic potential vorticity (QGPV) of Saturn's polar regions at the same altitude is around 20 times larger than the potential vorticity of the north polar vortex on Earth
We compute quasi‐geostrophic potential vorticity (QGPV) maps of Saturn's north and south polar regions between 68° and 90° planetographic latitude for different pressures between the upper troposphere (500 mbar) and upper stratosphere (1 mbar) for June 2013, December 2008, and October 2006
Summary
Saturn's rotation axis is tilted at an angle of 26.7° relative to its orbital plane, causing substantial seasonal variations of insolation over a 29.5‐year cycle (one Saturnian solar orbit). We analyze the temporal changes in the potential vorticity maps looking for possible seasonal effects, and we find that changes are mainly related to the seasonal evolution of the temperature fields, since zonal winds remain essentially stable at cloud level This way, we provide a diagnostic of the behavior of the polar dynamics in a planetary atmosphere different to Earth, and subject to seasonal insolation changes, giving important information about the nature of waves and dynamical instabilities in those regions. We use higher‐resolution thermal and wind profiles, which might help the understanding of the very particular dynamics of Saturn's polar regions
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