Noble Gas Diffusion Mechanism in Lunar Soil Simulant Grains: Results from ^4He^+ Implantation and Extraction Experiments

Experiments on ion implantation were performed in order to better characterize diffusion of noble gases in lunar soil. ^4He^+ at 50 keV with 5×10^16 ions/cm^2 was implanted into lunar simuiants and crystal ilmenite. Helium in the samples was released by stepwise heating experiments. Based on the dat...

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Published in:Journal of earth science (Wuhan, China) China), 2011-10, Vol.22 (5), p.566-577
Main Author: 付晓辉 邹永廖 郑永春 贺怀宇 欧阳自远
Format: Article
Language:English
Subjects:
Biogeosciences
Earth and Environmental Science
Earth Sciences
Geochemistry
Geology
Geotechnical Engineering & Applied Earth Sciences
加热实验
土壤颗粒
惰性气体
扩散机制
提取
月球土壤
模拟物
离子注入
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description Experiments on ion implantation were performed in order to better characterize diffusion of noble gases in lunar soil. ^4He^+ at 50 keV with 5×10^16 ions/cm^2 was implanted into lunar simuiants and crystal ilmenite. Helium in the samples was released by stepwise heating experiments. Based on the data, we calculated the helium diffusion coefficient and activation energy. Lunar simulants dis- play similar ^4He release patterns in curve shape as lunar soil, but release temperatures are a little lower. This is probably a consequence of long-term diffusion after implantation in lunar soil grains. Variation of activation energy was identified in the Arrhenius plots of lunar simulants and Panzhihua (攀枝花) ilmenite. We conclude that noble gas release in lunar soil cannot be described as simple thermally activated volume diffusion. Variation of diffusion parameters could be attributed to physical transformation during high temperature. Radiation damage probably impedes helium diffusion. However, bubble radius growth during heating does not correlate with activation energy variation. Activation energy of Panzhihua ilmenite is 57.935 kJ/mol. The experimental results confirm that ilmenite is more retentive for noble gas than other lunar materials.
doi_str_mv 10.1007/s12583-011-0207-4
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subjects Biogeosciences
Earth and Environmental Science
Earth Sciences
Geochemistry
Geology
Geotechnical Engineering & Applied Earth Sciences
加热实验
土壤颗粒
惰性气体
扩散机制
提取
月球土壤
模拟物
离子注入
title Noble Gas Diffusion Mechanism in Lunar Soil Simulant Grains: Results from ^4He^+ Implantation and Extraction Experiments
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