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Global Venus‐Solar Wind Coupling and Oxygen Ion Escape

Moa Persson, Yoshifumi Futaana, Robin Ramstad, Audrey Schillings, Kei Masunaga, H. Nilsson, A. Fedorov, S. Barabash

2021Geophysical Research Letters13 citationsDOIOpen Access PDF

Abstract

Abstract The present‐day Venusian atmosphere is dry, yet, in its earlier history a significant amount of water evidently existed. One important water loss process comes from the energy and momentum transfer from the solar wind to the atmospheric particles. Here, we used measurements from the Ion Mass Analyzer onboard Venus Express to derive a relation between the power in the upstream solar wind and the power leaving the atmosphere through oxygen ion escape in the Venusian magnetotail. We find that on average 0.01% of the available power is transferred, and that the percentage decreases as the available energy increases. For Mars the trend is similar, but the efficiency is higher. At Earth, the ion escape does not behave similarly, as the ion escape only increases after a threshold in the available energy is reached. These results indicate that the Venusian induced magnetosphere efficiently screens the atmosphere from the solar wind.

Topics & Concepts

VenusSolar windAtmosphere (unit)Atmosphere of VenusAtmospheric sciencesEnvironmental scienceMars Exploration ProgramAstrobiologyOxygenIonMagnetospherePhysicsMeteorologyPlasmaQuantum mechanicsPlanetary Science and ExplorationAstro and Planetary ScienceSolar and Space Plasma Dynamics