通过石英断裂和多金属熔滴生长实现金的超富集

Geology Pub Date : 2024-02-28 DOI:10.1130/g51875.1
Wei Jian, Jingwen Mao, Bernd Lehmann, Nigel J. Cook, Jiankang Li, Shiwei Song, Lei Zhu
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摘要

热液系统中的金沉淀传统上被认为是由于矿液物理化学条件的变化导致金络合物稳定性下降而引起的金过饱和。然而,造山(剪切带相关)金矿床中的超高品位金矿脉每吨可含金千克或更多,这与流体中通常极低的金浓度(十亿分之几十)形成鲜明对比。金矿物组合通常仅限于原生金和/或金-(银)碲化物,出现在剪切石英脉的微裂隙中。通过对此类集合体的纹理和成分特征进行分析,并结合热液金刚石砧室实验和加热冷冻实验,证明了另一种超高品位金富集机制是通过石英断裂引起的多金属熔体液滴的生长实现的。我们提出,富含 Au-Ag-Te-Bi- 的多金属熔滴是通过金属复合物在断裂石英表面的吸附-还原作用形成的,其中表面硅醇基团和氢是还原剂。随后,熔滴通过催化金属络合物的还原,并吸收断裂石英网络中渗透流体中的金属而增长。具有流动性和反应性的多金属熔滴可以在长期的石英断裂过程中反复与流体发生反应,并有效地持续从多次金不饱和矿石流体中清除金。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Hyper-enrichment of gold via quartz fracturing and growth of polymetallic melt droplets
Gold precipitation in hydrothermal systems is traditionally attributed to supersaturation of gold due to decreasing gold complex stability triggered by changes in physicochemical conditions of the ore fluid. However, ultrahigh-grade gold veins in orogenic (shear zone related) gold deposits can contain kilograms per tonne of gold or more, in marked contrast to the typically very low gold concentrations (tens of parts per billion) in fluid. The gold mineral assemblage is commonly restricted to native gold and/or Au-(Ag)-tellurides and occurs in micro-fractures of sheared quartz veins. Textural and compositional characterization of such assemblages, coupled with hydrothermal diamond anvil cell experiments and heating-freezing experiments, provides evidence for an alternative ultrahigh-grade gold enrichment mechanism via growth of polymetallic melt droplets induced by quartz fracturing. We propose that polymetallic melt droplets of Au-Ag-Te-Bi−rich composition form through adsorption-reduction of metal complexes on fractured quartz surfaces, where surface silanol groups and hydrogen serve as reductants. The melt droplets subsequently grow by catalyzing reduction of metal complexes and absorbing metals from fluids percolating in the fractured quartz network. The mobile and reactive polymetallic melt droplets can repeatedly react with the fluid on protracted quartz fracturing and efficiently continue to scavenge gold from multiple pulses of gold-undersaturated ore fluids.
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