Molecular Dynamics Simulations of Dielectric Breakdown of Lunar Regolith: Implications for Water Ice Formation on Lunar Surface

被引:8
作者
Huang, Ziyu [1 ]
Nomura, Ken-ichi [2 ]
Nakano, Aiichiro [3 ]
Wang, Joseph [1 ]
机构
[1] Univ Southern Calif, Dept Astronaut Engn, Los Angeles, CA 90007 USA
[2] Univ Southern Calif, Dept Chem Engn & Mat Sci, Los Angeles, CA USA
[3] Univ Southern Calif, Dept Comp Sci, Los Angeles, CA USA
来源
GEOPHYSICAL RESEARCH LETTERS | 2021年 / 48卷 / 03期
关键词
deep dielectric charging; dielectric breakdown; lunar regolith; molecular dynamics simulations; water formation; space weather; SOLAR-WIND IMPLANTATION; OH/H2O; MOON; RETENTION;
D O I
10.1029/2020GL091681
中图分类号
P [天文学、地球科学];
学科分类号
07 ;
摘要
Molecular dynamics simulations are carried out to investigate dielectric breakdown of lunar regolith induced by space weather events and its potential effects on water ice formation on lunar surface. We find that dielectric breakdown can trigger the water formation process by breaking the chemical bonds of regolith grains and exposing the oxygen atoms to react with the hydrogen implanted by solar wind. In the permanently shadowed region, the water molecules formed become attached to regolith grains in the molecular structure of ice after the event. Thus, dielectric breakdown can also enable the preservation of water molecules by changing the hydrophobicity of regolith grains.
引用
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页数:8
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共 46 条
[1]   Morphological and Spectral Characterization of Lunar Regolith Breakdown due to Water Ice [J].
Shackelford, A. ;
Hanna, K. L. Donaldson ;
Horton, M. ;
Noce, D. .
PLANETARY SCIENCE JOURNAL, 2024, 5 (01)
[2]   Molecular Dynamics Simulations of Water Formation and Retention by Micrometeoroid Impact on Lunar Surface [J].
Huang, Ziyu ;
Nomura, Ken-ichi ;
Wang, Joseph .
GEOPHYSICAL RESEARCH LETTERS, 2021, 48 (15)
[3]   The formation of molecular hydrogen from water ice in the lunar regolith by energetic charged particles [J].
Jordan, A. P. ;
Stubbs, T. J. ;
Joyce, C. J. ;
Schwadron, N. A. ;
Spence, H. E. ;
Wilson, J. K. .
JOURNAL OF GEOPHYSICAL RESEARCH-PLANETS, 2013, 118 (06) :1257-1264
[4]   Lunar regolith water ice simulation method and characterization [J].
Tian, Ye ;
Tang, Junyue ;
Jiang, Shengyuan ;
Zhang, Weiwei ;
Pang, Yong ;
Jiang, Jihang ;
Liu, Ziheng ;
Li, Yang ;
Zou, Meng ;
Wang, Desen .
ICARUS, 2024, 417
[5]   Direct measurement of hydroxyl in the lunar regolith and the origin of lunar surface water [J].
Liu, Yang ;
Guan, Yunbin ;
Zhang, Youxue ;
Rossman, George R. ;
Eiler, John M. ;
Taylor, Lawrence A. .
NATURE GEOSCIENCE, 2012, 5 (11) :779-782
[6]   Untangling the formation and liberation of water in the lunar regolith [J].
Zhu, Cheng ;
Crandall, Parker B. ;
Gillis-Davis, Jeffrey J. ;
Ishii, Hope A. ;
Bradley, John P. ;
Corley, Laura M. ;
Kaiser, Ralf I. .
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA, 2019, 116 (23) :11165-11170
[7]   The rate of dielectric breakdown weathering of lunar regolith in permanently shadowed regions [J].
Jordan, A. P. ;
Stubbs, T. J. ;
Wilson, J. K. ;
Schwadron, N. A. ;
Spence, H. E. .
ICARUS, 2017, 283 :352-358
[8]   Lunar regolith and water ice escape due to micrometeorite bombardment [J].
Pabari, J. P. ;
Nambiar, S. ;
Shah, V ;
Bhardwaj, Anil .
ICARUS, 2020, 338
[9]   Studies of Isotopic Fractionation of D/H Water Ice in Lunar Regolith [J].
Sevastyanov, V. S. ;
Krivenko, A. P. ;
Voropaev, S. A. ;
Marov, M. Ya. .
SOLAR SYSTEM RESEARCH, 2023, 57 (06) :505-515
[10]   Conditions of condensate rim formation on the surface of lunar regolith particles [J].
O. I. Yakovlev ;
M. V. Gerasimov ;
Yu. P. Dikov .
Geochemistry International, 2011, 49 :967-973
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