Migration of Water Molecules in the Permanently Shaded Areas of Polar Areas of Mercury

Radar observations of the surface of Mercury had revealed areas with bright reflective properties in both polar regions of the planet. It was suggested that such areas contain depositions of volatile compounds, including water. In this paper, we investigated migration of water molecules to the perma...

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Bibliographic Details
Published inEarth, moon, and planets Vol. 125; no. 2; p. 5
Main Authors Feoktistova, E. A., Zharkova, A. Y., Kokhanov, A. A., Rodionova, Zh F.
Format Journal Article
LanguageEnglish
Published Dordrecht Springer Netherlands 01.10.2021
Springer Nature B.V
Subjects
Astronomy
Astrophysics and Astroparticles
Cold traps
Escape velocity
Exosphere
Mercury
Mercury (planet)
Mercury exosphere
Mercury surface
Monte Carlo simulation
North Pole
Observations and Techniques
Photolysis
Physics
Physics and Astronomy
Planetology
Planets
Polar environments
Polar regions
Radar
South Pole
Space Exploration and Astronautics
Space Sciences (including Extraterrestrial Physics
Volatile compounds
Water chemistry
Polar region
Craters
Mercury
Volatiles
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Summary:Radar observations of the surface of Mercury had revealed areas with bright reflective properties in both polar regions of the planet. It was suggested that such areas contain depositions of volatile compounds, including water. In this paper, we investigated migration of water molecules to the permanently shaded areas, located in the impact crater in the polar regions of Mercury. To simulate the migration of water molecules in the exosphere of Mercury, we used the Monte Carlo method. To estimate the proportion of water molecules falling into cold traps in the polar regions of Mercury, we estimated the area of such regions. We found that the area of permanently shaded areas near the north pole of the planet reaches 23,300 km 2 , and in the area of the south pole—45,500 km 2 . Most of the water molecules (~ 92%) will be destroyed as a result of photolysis, and ~ 7.5% of them will be destroyed while they are on the planet's surface between hops. The fraction of water molecules that left the planet's exosphere as a result of reaching the escape velocity is only 0.3%. The fraction of water molecules trapped in permanently shaded areas in the polar regions of Mercury reaches 7.8% of the total number of particles participating in the simulation. Only 2.2% of them can be trapped in cold traps in the North Pole region and 5.6% in the South Pole region.
ISSN:0167-9295
1573-0794
DOI:10.1007/s11038-021-09542-2