通过铷锶同位素系统学重新审视月球正长岩的形成

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Qing Zhou , Heng-Ci Tian , Liyu Shan , Sen Hu , Wei Yang , Maoyong He , Lei Zhang , Yangting Lin , Xianhua Li
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引用次数: 0

摘要

KREEP(钾、稀土元素和磷)、来自地幔的岩浆熔体和被困液体融入月球铁质正长岩套件(FAN),在产生其地球化学和同位素变化方面发挥了关键作用。然而,这些不同成分的具体参与程度和不同作用仍存在争议。本研究提供了在月球长石陨石中发现的 28 个正长岩碎屑的原位锶同位素数据,以追踪它们的来源和后期改造过程。我们发现,这些斜长岩的 87Sr/86Sr 测量值(0.69978-0.70357)变化很大,与在阿波罗 16 号陨石中观察到的相对较窄的范围形成鲜明对比,从而可能反映了月壳岩石化学成分的多样性。相比之下,所分析的斜长石的 87Rb/86Sr 比值(0.00185-0.03962)一直较低,与阿波罗样本类似,反映了撞击引起的 Rb 损失。详细的调查表明,某些 87Sr/86Sr 比值升高可能不是由地面污染或仪器分析造成的,而很可能是由初始 87Rb/86Sr 高于 0.0119-0.1380 的 87Rb 源衰变造成的。然而,这种 87Rb/86Sr 值的升高不可能仅仅是月球岩浆海洋(LMO)结晶的结果,很可能涉及 KREEP 成分。结合痕量元素数据,我们估计了 KREEP 熔体在月球正长岩形成过程中所占的最大比例。未来对中国嫦娥五号和嫦娥六号任务采集的月球正长岩进行分析,对于验证观测到的锶同位素异质性至关重要。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Revisiting the formation of lunar anorthosites via the RbSr isotope systematics

The incorporation of KREEP (potassium, rare-earth element, and phosphorus), mantle-derived mafic melts and trapped liquid into the lunar ferroan anorthosite (FAN) suite plays a pivotal role in generating their geochemical and isotopic variations. Nonetheless, the specific involvement and distinct roles of these different components remain controversial. This study presents in-situ Sr isotopic data for 28 anorthositic clasts found within lunar feldspathic meteorites to trace their sources and post-modification processes. We find that these plagioclases exhibit substantial variations in their measured 87Sr/86Sr values (0.69978–0.70357), in contrast to the relatively narrow range observed in Apollo 16 FANs, thereby likely reflecting a diverse chemical composition of lunar crustal rocks. In contrast, the analyzed plagioclases have consistently low 87Rb/86Sr ratios (0.00185–0.03962), similar to those of Apollo samples, reflecting impact-induced loss of Rb. Detailed investigations indicate that certain elevated 87Sr/86Sr ratios are probably not caused by terrestrial contamination or instrumental analysis, but most likely result from the decay of 87Rb from sources with initial 87Rb/86Sr higher than 0.0119–0.1380. However, such elevated 87Rb/86Sr values cannot solely result from crystallization of the lunar magma ocean (LMO) and likely involve KREEP components. Combined with trace element data, we estimate the maximum proportion of KREEP melt in the formation of lunar anorthosites. Future analyses of lunar anorthosites collected by China's Chang'e-5 and Chang'e-6 missions will be crucial for validating the observed Sr isotopic heterogeneity.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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