EGU2020-17962
https://doi.org/10.5194/egusphere-egu2020-17962
EGU General Assembly 2020
© Author(s) 2021. This work is distributed under
the Creative Commons Attribution 4.0 License.

The distribution and saturation of water vapor as inferred from ACS during the first Martian year of TGO Science observations

Anna Fedorova1, Franck Montmessin2, Oleg Korablev1, Mikhail Luginin1, Alexander Trokhimovskiy1, Denis Belyaev1, Juan Alday3, Nikolay Ignatiev1, Franck Lefevre2, Kevin Olsen3, Ehouarn Millour4, Jean-Loup Bertaux2, Alexey Shakun1, Alexey Grigoriev1, Andrey Patrakeev1, Svyatoslav Korsa1, Colin Wilson3, Francois Forget4, and Anna Maattanen2
Anna Fedorova et al.
  • 1Space Research Institute (IKI) RAS, Physics of planets, Moscow, Russian Federation (fedorova@iki.rssi.ru)
  • 2LATMOS-UVSQ, Guyancourt, France
  • 3Physics Department, Oxford University, Oxford, United Kingdom
  • 4LMD, Sorbonne Université, CNRS, Jussieu, Paris, France

The water vapour vertical distribution is an eloquent gauge of the relative roles of the various sources, sinks and processes that control the Martian water cycle. However, its behaviour is still poorly studied while it is instrument for our understanding of the loss of water from Mars to space, which results from the transport of water to the upper atmosphere where it is disassociated to hydrogen atoms that later escape. We use the Atmospheric Chemistry Suite on the ExoMars Trace Gas Orbiter to characterize the water distribution with altitude. Here we present results of the Atmospheric Chemistry Suite (ACS) instrument NIR channel for the first year of TGO observations covering the almost full year from Ls 160° of the Martian year 34 (April 2018) to Ls 130° of the Martian year 35 (January 2020). Simultaneous measurements of the water vapour mixing ratio, temperature and dust vertical distribution and formation of water ice clouds allow us to constrain the complex water behaviour and estimate the saturation state of H2O. Water profiles during the 2018-2019 southern spring and summer stormy seasons show that high altitude water is preferentially supplied close to perihelion and that large supersaturation occurs even when clouds are present. Here we attempt to complete the story by studying water vapor during the northern spring and summer to explore whether saturation impacts water transport between hemispheres in this season. The data analysis of MY35 was supported by RSF (project No. 20-42-09035).

How to cite: Fedorova, A., Montmessin, F., Korablev, O., Luginin, M., Trokhimovskiy, A., Belyaev, D., Alday, J., Ignatiev, N., Lefevre, F., Olsen, K., Millour, E., Bertaux, J.-L., Shakun, A., Grigoriev, A., Patrakeev, A., Korsa, S., Wilson, C., Forget, F., and Maattanen, A.: The distribution and saturation of water vapor as inferred from ACS during the first Martian year of TGO Science observations, EGU General Assembly 2020, Online, 4–8 May 2020, EGU2020-17962, https://doi.org/10.5194/egusphere-egu2020-17962, 2020.

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