Abstract
Aqueous complexation has long been considered the only viable means of transporting gold to depositional sites in hydrothermal ore-forming systems. A major weakness of this hypothesis is that it cannot readily explain the formation of ultrahigh-grade gold veins. This is a consequence of the relatively low gold concentrations typical of ore fluids (tens of parts per billion [ppb]) and the fact that these "bonanza" veins can contain weight-percent levels of gold in some epithermal and orogenic deposits. Here, we present direct evidence for a hypothesis that could explain these veins, namely, the transport of the gold as colloidal particles and their flocculation in nanoscale calcite veinlets. These gold-bearing nanoveinlets bear a remarkable resemblance to centimeter-scale ore veins in many hydrothermal gold deposits and give unique insight into the scale invariability of colloidal flocculation in forming hyperenriched gold deposits. Using this evidence, we propose a model for the development of bonanza gold veins in high-grade deposits. We argue that gold transport in these systems is largely mechanical and is the result of exceptionally high degrees of supersaturation that preclude precipitation of gold crystals and instead lead to the formation of colloidal particles, which flocculate and form much larger masses. These flocculated masses aggregate locally, where they are seismically pumped into fractures to locally form veins composed largely of gold. This model explains how bonanza veins may form from fluids containing ppb concentrations of gold and does not require prior encapsulation of colloidal gold particles in silica gel, as proposed by previous studies.
Highlights
Aqueous complexation has long been considered the only viable means of transporting gold to depositional sites in hydrothermal ore-forming systems
The existence of gold colloids has been known since the midnineteenth century [6], and the idea that gold deposits might form from fluids transporting the gold as a colloid was proposed more than 80 y ago [7,8,9]
Formation of such bonanza veins by direct precipitation of native gold or electrum from the ore fluids would require that individual fractures remain open for unreasonably long periods of time [>>50,000 y [1], which is a timeframe that exceeds the total lifespan of many porphyry–epithermal deposits [3] and greatly exceeds the estimated ∼1,400 y required to seal a 1-m-wide vein grading 20 g/t Au in an active geothermal system [4]] or that the fluid flux be extraordinarily high
Summary
Measurements of gold concentrations in the fluids responsible for epithermal mineralization and in geothermal fluids, which are considered to be analogs of epithermal ore fluids, are on the order of 10 to 30 parts per billion (ppb) [1]. Similar concentrations have been calculated for fluids of appropriate composition from the results of experiments designed to determine the speciation of gold in aqueous fluids [2] Such concentrations may be sufficient to form veins containing tens of grams per tonne of gold, they are far too low to explain spatially discrete occurrences of ultrahigh-grade concentrations which, in some veins, exceed 50 wt % of gold per tonne on the decimeter scale; these bonanza intervals are commonly accompanied by intervals in the same vein containing
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