Barium isotope evidence for a magmatic fluid-dominated petrogenesis of LCT-type pegmatites

IF 3.4 1区地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS

Geochemical Perspectives Letters Pub Date : 2024-06-28 DOI:10.7185/geochemlet.2426

G. Deng, D. Jiang, G. Li, Z. Xu, F. Huang

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Abstract

Understanding the petrogenesis of granitic pegmatites associated with Li mineralisation is fundamental in constraining rare metal enrichment mechanisms. However, there is still significant controversy surrounding the central issue of the nature of pegmatite-forming liquids. Here, we report Ba isotope data for a 3000 m borehole in the Jiajika pegmatite field that hosts the largest hard rock-type Li deposit in Asia. The pegmatites exhibit markedly lower δ^138/134Ba than the wall rocks and the average upper continental crust, which cannot be attributed to low degree anatexis of metasedimentary or crystal fractionation of highly evolved granitic magmas. Instead, modelling suggests that their low δ^138/134Ba most likely results from substantial involvement (10–40 %) of isotopically light hydrothermal fluids exsolved from the underlying magmatic reservoirs. In the context of transcrustal magmatic system, these magmatic fluid components may be a key medium in extracting, concentrating, and transporting Li to provide a material source for mineralisation in granitic pegmatites.

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以岩浆流体为主的岩浆岩成岩作用的钡同位素证据

了解与锂矿化有关的花岗伟晶岩的岩石成因，对于制约稀有金属富集机制至关重要。然而，围绕伟晶岩成岩液性质这一核心问题仍存在重大争议。在此，我们报告了亚洲最大的硬岩型锂矿床--嘉积嘉伟晶岩矿区一个 3000 米钻孔的钡同位素数据。伟晶岩的δ138/134Ba明显低于壁岩和平均上部大陆地壳，这不能归因于变质岩的低度无性化或高度演化的花岗岩岩浆的晶体分馏。相反，模拟结果表明，它们的低δ138/134Ba 很可能是由于大量（10-40%）同位素轻的热液从底层岩浆储层中流出造成的。在跨地壳岩浆系统中，这些岩浆流体成分可能是萃取、浓缩和运输锂的关键介质，为花岗伟晶岩的成矿提供了物质来源。

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来源期刊

Geochemical Perspectives Letters Earth and Planetary Sciences-Geochemistry and Petrology

CiteScore

7.00

自引率

2.00%

发文量

审稿时长

15 weeks

期刊介绍： Geochemical Perspectives Letters is an open access, internationally peer-reviewed journal of the European Association of Geochemistry (EAG) that publishes short, highest-quality articles spanning geochemical sciences. The journal aims at rapid publication of the most novel research in geochemistry with a focus on outstanding quality, international importance, originality, and stimulating new developments across the vast array of geochemical disciplines.