4.6 Article

Chemical and physical heterogeneity within native gold: implications for the design of gold particle studies

Journal

MINERALIUM DEPOSITA
Volume 56, Issue 8, Pages 1563-1588

Publisher

SPRINGER
DOI: 10.1007/s00126-020-01036-x

Keywords

Natural gold; Microchemical characterization; Trace elements; Hydrothermal gold

Funding

  1. NERC [bgs06001] Funding Source: UKRI

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Studies of populations of gold particles are becoming increasingly common, but interpretation of compositional data may not be straightforward and require methods such as electron-probe-microanalysis and laser-ablation ICP mass spectrometry. Research shows that gold mainly forms homogeneous alloys with Ag, Cu, and Hg, while other elements are commonly distributed highly heterogeneously.
Studies of populations of gold particles are becoming increasingly common; however, interpretation of compositional data may not be straightforward. Natural gold is rarely homogenous. Alloy heterogeneity is present as microfabrics formed either during primary mineralization or by modification of pre-existing alloys by chemical and physical drivers during subsequent residence in either hypogene or surficial environments. In electron-probe-microanalysis (EPMA)-based studies, the combination of Cu, Hg, and Pd values and mineral inclusion suites may be diagnostic for source style of mineralization, but Ag alone is rarely sufficient. Gold characterization studies by laser-ablation-ICP mass spectrometry linked to both quadrupole and Time-of-Flight (ToF-MS) systems show that only Ag, Cu, and Hg form homogenous alloys with Au sufficiently often to act as generic discriminants. Where present, other elements are commonly distributed highly heterogeneously at the micron or submicron scale, either as mineral inclusions or in highly localized, but low concentrations. Drawing upon our own data derived from individual inspection and analyses of approximately 40,000 gold particles from 526 placer and in situ localities worldwide, we show that adequate characterization of gold from a specific locality normally requires study of a minimum of 150 particles via a two-stage approach comprising spatial characterization of compositional heterogeneity, plus crystallographic orientation mapping, that informs subsequent targeted acquisition of quantitative compositional data by EPMA and/or laser-ablation ICP-MS methods. Such data provide the platform to review current understanding of the genesis of gold particle characteristics, elevating future compositional studies from empirical descriptions to process-focused interpretations.

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