Combined sulfur, carbon and redox budget constraints on genetic models for the Here’s Your Chance Pb–Zn deposit, Australia

GeoResJ Pub Date : 2014-09-01 DOI:10.1016/j.grj.2014.09.001
Jeffrey M. Dick , Katy A. Evans , Alex I. Holman , David Leach , Kliti Grice
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引用次数: 3

Abstract

The formation of base metal sulfide deposits requires not only a source of metals but also reduced sulfur. If incoming sulfur is present in ore fluids as sulfate, then a source of electrons is needed to drive the reduction of sulfate to sulfide. The oxidation of organic matter can release electrons that provide the reducing capacity, whether it be in low- or high-temperature settings that are conducive to biological or thermochemical sulfate reduction (BSR or TSR). The amounts of organic matter reacted and sulfide minerals formed can be estimated by mass balance calculations. In this study, an integrated mass balance expression is formulated that takes into account the sulfide mineral content and organic carbon content and H/C ratios of mineralised and non-mineralised rocks. Model calculations based on carbon, sulfur and redox budget balances suggest that the extent of oxidation of the organic matter present at the Here’s Your Chance (HYC) Pb–Zn deposit is insufficient for reduction of the required quantity of sulfate. The results imply that externally derived reducing capacity and/or reduced sulfur is required to form the metal resource. Possible sources include hydrocarbon-rich fluids from deeper parts of the sedimentary sequence or formation of sulfide and organic matter as products of BSR during sedimentation/early diagenesis. However, the observed oxidation of organic matter associated with the deposit suggests that at least some reducing capacity is locally derived. Therefore, our calculations are consistent with genetic models for HYC that have multiple sources of redox budget for sulfate reduction.

澳大利亚铅锌矿综合硫、碳和氧化还原预算约束的遗传模型
贱金属硫化物矿床的形成不仅需要金属的来源,而且还需要还原硫。如果进入的硫以硫酸盐的形式存在于矿石流体中,那么就需要一个电子源来驱动硫酸盐还原为硫化物。有机物的氧化可以释放提供还原能力的电子,无论是在有利于生物或热化学硫酸盐还原(BSR或TSR)的低温或高温环境中。反应的有机物和形成的硫化物矿物的数量可以通过质量平衡计算来估计。在本研究中,建立了综合考虑矿化和非矿化岩石中硫化物矿物含量、有机碳含量和H/C比值的质量平衡表达式。基于碳、硫和氧化还原收支平衡的模型计算表明,在这里你的机会(HYC)铅锌矿床中存在的有机物的氧化程度不足以减少所需的硫酸盐量。结果表明,形成金属资源需要外部获得的还原能力和/或还原硫。可能的来源包括来自沉积层序较深部分的富烃流体或沉积/早期成岩作用期间BSR的产物硫化物和有机质的形成。然而,观察到的与矿床有关的有机物氧化表明,至少有一些还原能力是局部产生的。因此,我们的计算结果与具有多种硫酸盐还原氧化还原预算来源的HYC遗传模型一致。
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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