The role of hydrothermal alteration in uranium mineralization at the Xiaoshan uranium deposit, South China

IF 3.2 2区 地球科学 Q1 GEOLOGY
Fu-Rong Li , Yong Zhang , Fei-Peng Dang , Di Huang , Fu-Jun Zhong , Jie Yan , Fei Xia , Chun-Rong Pan , Jia-Yong Pan , Shan-Chu Han , Guo-Qi Liu , Xiao-Tian Zhang , Ying Liu , Kai-Xing Wang
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Abstract

Hydrothermal alteration can be utilized to constrain element migrations during mineralization, as it records the effects of fluid-rock interactions. Previous studies have suggested that uranium in deposits primarily originates from uranium-bearing granites; however, limited knowledge exists regarding the leaching mechamisms of this element and rare earth elements (REEs) from these rocks. In recent years, the Xiaoshan Deposit, a newly discovered medium-sized uranium deposit, has been discovered in the central part of the Lujing uranium ore field, South China. In this study, we examine this deposit to investigate hydrothermal alterations and their impact on elemental mass change. The deposit exhibits seven types of alteration including K-feldspar, albite, illite, sericite, muscovite, quartz and chlorite alteration. These alterations follow a certain sequence, starting from chlorite alteration, followed by widespread K-feldspar alteration, then to albite alteration, accompanied by muscovite alteration, and finally illite, sericite and quartz alteration. The main uranium mineralization stage was coeval with the late acid siliceous hydrothermal fluid, illite and sericite alteration. The pre-ore alkaline alteration (K-feldspar alteration) resulted in the leaching and extraction of uranium, leading to the precipitation of a significant amount of apatite in mineral interstices and initial uranium enrichment (ΔCi (U) = 16.52 ppm). This process facilitated material preparation for subsequent acidic alterations and localized ore enrichment. The original dense rock structure was disrupted, creating fractures/cavities that served as conduits for uranium mineralization. Moreover, under alkaline metasomatism, uranium and REEs was extensively leached out of uranium-bearing accessory minerals such as the apatite. According to apatite compositional variations and alteration geochemistry, these variations reveal the process of uranium dissolution, migration, and precipitation enrichment into ore bodies. Uranium was completely released during alkaline metasomatism, causing a sharp decline in U content from 53.1 ppm to 0.96 ppm. The formation of alkaline alteration fluids facilitates the extraction of uranium from the surrounding rocks (the Indosinian granite).

Abstract Image

热液蚀变在华南萧山铀矿床铀矿化中的作用
热液蚀变可用于制约成矿过程中的元素迁移,因为它记录了流体-岩石相互作用的影响。以往的研究表明,矿床中的铀主要来源于含铀花岗岩,但对这些岩石中铀元素和稀土元素(REEs)的浸出机理了解有限。近年来,在中国南方陆井铀矿田的中部发现了一个新的中型铀矿床--萧山矿床。在本研究中,我们对该矿床进行了考察,以研究热液蚀变及其对元素质量变化的影响。该矿床呈现出七种蚀变类型,包括钾长石蚀变、白云石蚀变、伊利石蚀变、绢云母蚀变、褐铁矿蚀变、石英蚀变和绿泥石蚀变。这些蚀变遵循一定的顺序,从绿泥石蚀变开始,然后是广泛的钾长石蚀变,接着是白云石蚀变,伴随着褐铁矿蚀变,最后是伊利石、绢云母和石英蚀变。主要的铀矿化阶段与后期的酸性硅质热液、伊利石和绢云母蚀变共生。前矿石碱性蚀变(钾长石蚀变)导致了铀的浸出和提取,使大量磷灰石在矿物间隙中沉淀,并使铀得到初步富集(ΔCi (U) = 16.52 ppm)。这一过程有助于为随后的酸性蚀变和局部矿石富集做好材料准备。原有的致密岩石结构被破坏,形成裂缝/空洞,成为铀矿化的通道。此外,在碱性变质作用下,铀和稀土元素从磷灰石等含铀附属矿物中被大量浸出。根据磷灰石成分变化和蚀变地球化学,这些变化揭示了铀溶解、迁移和沉淀富集到矿体的过程。铀在碱性变质过程中完全释放出来,导致铀含量从百万分之 53.1 急剧下降到百万分之 0.96。碱性蚀变液的形成有利于从周围岩石(印多西尼花岗岩)中提取铀。
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来源期刊
Ore Geology Reviews
Ore Geology Reviews 地学-地质学
CiteScore
6.50
自引率
27.30%
发文量
546
审稿时长
22.9 weeks
期刊介绍: Ore Geology Reviews aims to familiarize all earth scientists with recent advances in a number of interconnected disciplines related to the study of, and search for, ore deposits. The reviews range from brief to longer contributions, but the journal preferentially publishes manuscripts that fill the niche between the commonly shorter journal articles and the comprehensive book coverages, and thus has a special appeal to many authors and readers.
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