The impacts of solar wind on the Martian upper atmosphere [CL]

http://arxiv.org/abs/2210.01417


Since the first in-situ measurements of the altitude profile of upper atmospheric density and composition were carried out by the Viking lander missions in 1976, similar data are continuously gathered by MAVEN and MOM spacecraft orbiting Mars since their launch in September 2014 with mass spectrometers and other related payloads. Using near-simultaneous observations by the two orbiters, it is seen that both data sets indicate significant day-to-day variations of Argon density profiles in the thermosphere-exosphere, 150-300 km region, during the period 1-15, June 2018, when the solar EUV radiation did not show any appreciable change but the solar wind energetic particle fluxes did so. Extending this study to include the other parent atmospheric constituents carbon dioxide, helium, nitrogen and their photochemical products atomic oxygen, and carbon monoxide during the same period it is found that the density profiles of carbon dioxide and atomic oxygen also show similar variations with carbon dioxide densities showing an increasing trend similar to Argon, but a reversal of this trend for atomic oxygen densities. Using insitu and near simultaneous measurements of solar EUV fluxes and the solar wind plasma velocities and densities near MAVEN periapsis it is noted that, unlike the solar EUV radiation, solar wind parameters showed a decrease by a factor of 2-3. Hence, it is inferred that the energetic and penetrating solar wind charged particle impact-driven dissociation, ionisation and ion-chemical processes could decrease the carbon dioxide densities leading to an increase in atomic oxygen densities. This result is also discussed from the considerations of the proton gyro radius effect, pickup ions, sputtering, energetic neutral atoms driven ionisation and ion losses. Further data and modelling efforts would be necessary to confirm this finding.

Read this paper on arXiv…

K. Nagaraja and S. Chakravarty
Wed, 5 Oct 22
39/73

Comments: 20 pages, 10 figures