Instantaneous Three-dimensional Thermal Structure of the South Polar Vortex of Venus

Abstract

The Venus thermal radiation spectrum exhibits the signature of CO2 absorption bands. By means of inversion techniques, those bands enable the retrieval of atmospheric temperature profiles. We have analyzed VIRTIS-M-IR night-side data obtaining high-resolution thermal maps of Venus south polar region between 55 and 85 km altitudes for three dynamical configurations of the vortex. The cold collar is clearly distinguishable at 62 km altitude level, and it is more than 15 K colder than the pole on average. The South Polar Vortex appears as a vertically extended hot region close to the pole and squeezed by the cold collar between altitudes 55 and 67 km but spreading equatorward at about 74 km. Both the instantaneous temperature maps and their zonal averages show that the top altitude limit of the thermal signature of the vortex is at 80 km altitude, at least on the night-side of the planet. The upper part of the atmosphere (67 - 85 km) is more homogeneous and has long-scale horizontal temperature differences of about 25 K over horizontal distances of 2,000 km. The lower part (55 - 67 km) shows more fine-scale structure, creating the vortex' morphology, with thermal differences of up to about 50 K over 500 km horizontal distances. We also study the vertical stability of different atmospheric layers within the 55 - 85 km altitude range for the three vortex configurations. It is always positive, but the cold collar is the most vertically stable structure at polar latitudes, while the vortex and sub-polar latitudes show lower stability values. Furthermore, the hot filaments present within the vortex exhibit lower stability values than their surroundings. The layer between 62 and 67 km resulted to be the most stable. These results are in good agreement with conclusions from previous radio occultation analyses.