The Magmatic–Hydrothermal Transition in Lithium Pegmatites: Petrographic and Geochemical Characteristics of Pegmatites from the Kamativi Area, Zimbabwe

The Canadian Mineralogist Pub Date : 2021-01-11 DOI:10.3749/canmin.2100032

R. Shaw, K. Goodenough, É. Deady, P. Nex, Brian Ruzvidzo, J. Rushton, I. Mounteney

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引用次数: 4

Abstract

Lithium is a critical metal, vital for electrification of transport. Currently, around half the world's lithium is extracted from rare-metal pegmatites and understanding the genesis and evolution of these igneous rocks is therefore essential. This paper focuses on the pegmatites in the Kamativi region of Zimbabwe. A group of early pegmatites is distinguished from a late pegmatite suite which includes the ca. 1030 Ma Main Kamativi Pegmatite. Previously mined for tin, the mine tailings are now being investigated for lithium. Mineral-scale investigation of samples from the Main Kamativi Pegmatite has allowed recognition of a four-stage paragenesis: (1) an early magmatic assemblage dominated by quartz, alkali feldspar, spodumene (LiAlSi2O6) and montebrasite [LiAl(PO4)(OH, F)]; (2) partial alteration by widespread albitization, associated with growth of cassiterite and columbite group minerals; (3) irregular development of a quartz, muscovite, columbite group mineral assemblage; and (4) widespread low-temperature fluid-induced alteration of earlier phases to cookeite, sericite, analcime, and apatite. Whole-rock geochemistry indicates that the late pegmatites are enriched in Li, Cs, Ta, Sn, and Rb but depleted in Nb, Zr, Ba, Sr, and the rare earth elements relative to early pegmatites and country rock granitoids. A combination of field relationships and published dating indicates that the granitoids, and probably the early pegmatites, were emplaced toward the end of the ca. 2000 Ma Magondi Orogeny, whereas the late pegmatites are almost 1000 million years younger. The late pegmatites thus cannot be genetically related to the granitoids and are instead likely to have formed by partial melting of metasedimentary source rocks. The drivers for this melting may be related to crustal thickening along the northern margin of the Kalahari Craton during the assembly of Rodinia.

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锂伟晶岩的岩浆-热液转变:津巴布韦Kamativi地区伟晶岩的岩石学和地球化学特征

锂是一种至关重要的金属，对运输电气化至关重要。目前，世界上大约一半的锂是从稀有金属伟晶岩中提取的，因此了解这些火成岩的成因和演化是至关重要的。本文对津巴布韦卡马提维地区的伟晶岩进行了研究。一组早期伟晶岩与一套晚期伟晶岩相区别，其中包括约1030 Ma的主卡玛蒂伟晶岩。以前开采的是锡，现在正在对矿山尾矿进行锂的研究。对主卡玛第伟晶岩样品进行了矿物尺度研究，确认了四阶段共生作用:(1)早期岩浆组合以石英、碱长石、锂辉石(LiAlSi2O6)和蒙太白石[LiAl(PO4)(OH, F)]为主;(2)广泛的钠长石化引起的局部蚀变，与锡石和柱长石群矿物生长有关;(3)石英、白云母、柱长石群矿物组合发育不规则;(4)低温流体诱导的广泛早期蚀变为炊事石、绢云母、铝钙石和磷灰石。全岩地球化学特征表明，相对于早期辉晶岩和乡村岩石花岗质，晚期辉晶岩富集Li、Cs、Ta、Sn、Rb，而富集Nb、Zr、Ba、Sr和稀土元素。结合野外关系和已发表的年代测定结果表明，花岗岩类和早期伟晶岩可能是在大约2000年马鞍山造山运动结束时形成的，而晚期伟晶岩则要年轻近10亿年。因此，晚期伟晶岩不可能与花岗岩类有遗传关系，而可能是由变质沉积岩的部分熔融形成的。这种融化的驱动因素可能与罗迪尼亚聚集期间喀拉哈里克拉通北缘的地壳增厚有关。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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The Canadian Mineralogist

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