Presence of non-solar derived krypton and xenon unveiled by Chang'e-5 lunar soils
Xuhang Zhang, Fei Su, Guillaume Avice, Finlay M. Stuart, Yuanyuan Zheng, Ziheng Liu, Wei Guo, Thomas Smith, Runchuan Liu, Chao Lü, Ye He, Jiannan Li, Ranran Liu, Huaiyu He
Abstract
• Chang'e-5 lunar soil reveals a non-binary mixture. • Cometary and meteoritic component identified, adding to compositional diversity. • 134,136 Xe depletion link to cometary isotopes rather than early atmospheric escape. • Previous models insufficient in explaining Kr and Xe fractionation in lunar soils. • Chang'e-5 contributes to billions of years of solar system history. The extent of volatile elements on the surface and interior of the Moon remains a highly debated topic. Previous studies conducted on bulk lunar soil samples and solar wind samples collected by the Genesis mission indicate a discernible isotope mass- or non-mass-dependent fractionation of krypton and xenon. However, a detailed investigation of these processes is missing, particularly in determining the possible incorporation of cometary volatiles in the lunar regolith. New lunar soil samples returned by the Chang'e-5 mission provide a chance to answer these key questions. In this study, noble gas isotopes of nine subsamples from a Chang'e-5 scooped sample were analysed through stepwise-heating and total fusion laser extraction. The results reveal that a simple binary mixture of solar wind and cosmogenic components did not explain alone the isotopic composition of these samples. The Xe data shows insignificant amounts of atmospheric Xe and presents clear evidence of cometary contributions to the lunar regolith, with a significant depletion of 134,136 Xe compared to that in the solar wind. Additionally, a meteoritic component is identified. Compared to the Apollo results, our findings further validate the theory of Earth's atmospheric escape, substantiate the plausibility of these exogenous admixtures to elucidate the isotopic fractionation mechanisms of Kr and Xe within the lunar regolith, and provide novel insights into long-term constancy in the solar wind composition.