Petrological, chemical, and chronological study of breccias in the Chang'e‐5 soil-Reference-Cited by-同舟云学术

Petrological, chemical, and chronological study of breccias in the Chang'e‐5 soil

Published:2024-05-24 Issue:9 Volume:59 Page:2296-2320
ISSN:1086-9379
Container-title:Meteoritics & Planetary Science
language:en
Short-container-title:Meteorit & Planetary Scien

Author:

Shi Yuruo¹²^ORCID,Peng Wenxiao²³^ORCID,Joy Katherine H.⁴,Yu Xuefeng¹,Guan Yue⁵,Bao Zemin²,Che Xiaochao²,Tartèse Romain⁴^ORCID,Snape Joshua F.⁴^ORCID,Head James W.⁶,Whitehouse Martin J.⁷,Wang Xiaolei⁵,Qian Yuqi⁶,Li Zengsheng¹,Wang Chen²,Long Tao²,Xie Shiwen²,Fan Runlong²,Liu Jianhui²,Yang Zhiqing²,Yang Chun²,Wang Peizhi²,Liu Shoujie²,Wang Zhen²,Huang Haibin²,Kang Yuelan²,Sun Huiyi²,Zhang Wei²,Tian Lanlan⁵,Li Huawei⁸,Mao Xiaohong⁸,Shan Wei¹,Li Dapeng¹,Liu Dunyi¹²,Nemchin Alexander A.²⁹

Affiliation:

1. Key Laboratory of Gold Mineralization Processes and Resource Utilization, MNR Shandong Provincial Key Laboratory of Metallogenic Geological Process and Resource Utilization, Shandong Institute of Geological Sciences Jinan China

2. Beijing SHRIMP Center, Institute of Geology, Chinese Academy of Geological Sciences Beijing China

3. School of Earth Sciences and Resources China University of Geosciences Beijing China

4. Department of Earth and Environmental Sciences The University of Manchester Manchester UK

5. State Key Laboratory for Mineral Deposits Research, School of Earth Sciences and Engineering Nanjing University Nanjing China

6. Department of Earth, Environmental, and Planetary Sciences Brown University Providence Rhode Island USA

7. Department of Geosciences Swedish Museum of Natural History Stockholm Sweden

8. Institute of Geology, Chinese Academy of Geological Sciences Beijing China

9. School of Earth and Planetary Sciences Curtin University Perth Western Australia Australia

Abstract

AbstractWe carried out a petrological, mineralogical, and geochemical study of fragmental and regolith breccia clasts separated from two Chang'e‐5 (CE‐5) soil samples, CE5C0000YJYX03501GP and CE5C0400, which provide an opportunity to investigate the compositional change of regolith at the landing site through time. Fragmental breccia CE‐5‐B3 contains a diverse range of basaltic clasts and basaltic mineral fragments, and some rare Mg‐suite‐like minerals. Regolith breccias CE‐5‐B006, CE‐5‐B007, CE‐5‐B010‐08, CE‐5‐B010‐09, CE‐5‐B011‐07, and CE‐5‐B016‐03 contain mare basaltic fragments, mare vitrophyric clasts, rare Mg‐rich fragments possibly derived from the Mg‐suite rocks, and impact‐derived glass spherules. Pb‐isotope data obtained for baddeleyite grains found both inside some of the basaltic clasts identified in breccia fragments and in the breccia matrices yield Pb/Pb dates similar to the 2 Ga crystallization age of the CE‐5 basalt fragments, extracted directly from the soil sample. Seventy‐four Pb isotope analyses of Ca‐phosphate grains also indicate that the majority of these grains have Pb/Pb dates of 2 Ga, suggesting that they originate from the CE‐5 basalts. In addition, a Pb–Pb isochron drawn through analyses of four Ca‐phosphates in breccia CE5‐B006 yielded an intercept corresponding to a date of 3871 ± 46 Ma, which is the best possible estimate of the formation age of these four grains. Electron probe microanalysis shows that the breccias contain components similar to CE‐5 mare basalt fragments extracted directly from the soil sample, implying that the fragmental and regolith breccia fragments are mostly composed of material sourced from the underlying basalts. The general absence of impact melt breccia clasts, along with the general lack of Fe–Ni metal and absence of added meteoritic debris all suggest that the regolith at the CE‐5 landing site is immature and dominated by material mixed together by small local impact cratering events. Trace element analyses show that the glass beads in the regolith breccias have a Th abundance of 4.06–5.28 μg g−1. This is similar to the Th content of the regolith above the Em4 unit at the landing site as measured from orbit, as well as the estimated bulk Th content of CE‐5 basalts, suggesting that Th of the local regolith is predominantly sourced from the underlying mare basalts, without significant Th addition from Th‐rich exotic clasts sourced from evolved lunar lithologies.

Funder

National Natural Science Foundation of China

China National Space Administration

Publisher

Wiley

Link

https://onlinelibrary.wiley.com/doi/pdf/10.1111/maps.14192

Reference92 articles.

1. Baker A. E. Jolliff B. L. Yasanayake C. N. Denevi B. W. andLawrence S. J.2020.Lunar Agglutinate Glass Compositions and Comparison to Soil Grain‐Size Fractions.51st Lunar and Planetary Science Conference abstract #1321.

2. Baldridge W. Beaty D. Hill S. andAlbee A.1979.The Petrology of the Apollo 12 Pigeonite Basalt Suite.10th Lunar and Planetary Science Conference pp. 141–79.

3. Crystal‐Field Effects of Iron and Titanium in Selected Grains of Apollo 12, 14, and 15 Rocks, Glasses, and Fine Fractions;Bell P.;Proceedings of the Lunar Science Conference,1972

4. Compositional Variability of 2.0‐Ga Lunar Basalts at the Chang'e‐5 Landing Site

5. Brown G. Emeleus C. Holland J. andPhillips R.1970.Mineralogical Chemical and Petrological Features of Apollo 11 Rocks and their Relationship to Igneous Processes. Proceedings of the Apollo 11 Lunar Science Conference 1 1959–219.