Studies of Isotopic Fractionation of D/H Water Ice in Lunar Regolith

IF 0.6 4区物理与天体物理 Q4 ASTRONOMY & ASTROPHYSICS Solar System Research Pub Date : 2024-01-15 DOI:10.1134/S0038094623060060

V. S. Sevastyanov, A. P. Krivenko, S. A. Voropaev, M. Ya. Marov

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Abstract

In order to study the processes related to the origin and retention of water on the surface of the Moon, an experimental setup has been created at the Vernadsky Institute of Geochemistry and Analytical Chemistry, Russian Academy of Sciences (GEOKHI RAS), for the analysis of (re)sublimation processes of water ice in a vacuum at low temperatures. The temperature range for (re)sublimation varies from –100 to 0°C. The setup is connected to an Isotope Ratio Mass Spectrometer (IRMS), which allows for measuring the isotopic composition of the vapor of the evaporating substance and providing an estimation of the (re)sublimation rate under specific physicochemical conditions. The direct introduction of gases into the mass spectrometer in real-time mode sets the developed setup apart from foreign counterparts. The setup is equipped with a transparent quartz window through which the surface of the studied substance can be heated using a halogen lamp, simulating the movement of solar rays on the surface of mineral grain compositions under conditions similar to those on the lunar surface. In addition to studying gas (de)sorption on the surfaces of mineral grains of various compositions, the setup can also be used for researching the (re)sublimation of gas hydrates and CO₂.

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月球岩石中 D/H 水冰的同位素分馏研究

摘要为了研究与月球表面水的起源和保留有关的过程，俄罗斯科学院 Vernadsky 地球化学和分析化学研究所（GEOKHI RAS）建立了一个实验装置，用于分析水冰在真空中低温（再）升华的过程。再）升华的温度范围为 -100 至 0°C。该装置与同位素比质谱仪（IRMS）相连，可以测量蒸发物质蒸汽的同位素组成，并估算特定物理化学条件下的（再）升华速率。在实时模式下将气体直接引入质谱仪，使所开发的装置有别于国外同类装置。该装置配备了一个透明的石英窗口，可通过该窗口使用卤素灯加热被研究物质的表面，模拟太阳光在矿物颗粒成分表面的运动，其条件与月球表面类似。除了研究各种成分的矿物颗粒表面的气体（脱）吸附外，该装置还可用于研究气体水合物和二氧化碳的（再）升华。

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来源期刊

Solar System Research 地学天文-天文与天体物理

CiteScore

1.60

自引率

33.30%

发文量

审稿时长

6-12 weeks

期刊介绍： Solar System Research publishes articles concerning the bodies of the Solar System, i.e., planets and their satellites, asteroids, comets, meteoric substances, and cosmic dust. The articles consider physics, dynamics and composition of these bodies, and techniques of their exploration. The journal addresses the problems of comparative planetology, physics of the planetary atmospheres and interiors, cosmochemistry, as well as planetary plasma environment and heliosphere, specifically those related to solar-planetary interactions. Attention is paid to studies of exoplanets and complex problems of the origin and evolution of planetary systems including the solar system, based on the results of astronomical observations, laboratory studies of meteorites, relevant theoretical approaches and mathematical modeling. Alongside with the original results of experimental and theoretical studies, the journal publishes scientific reviews in the field of planetary exploration, and notes on observational results.