Magmatic vapor contraction and the transport of gold from the porphyry environment to epithermal ore deposits

Christoph A. Heinrich*, Thomas Driesner, Andri Stefánsson, Terry M. Seward

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

253 Citations (Scopus)

Abstract

Fluid-phase stability relations combined with thermodynamic modeling using fluid-inclusion analyses and new gold-solubility experiments lead to an integrated geological interpretation linking epithermal gold mineralization and porphyry-style ore formation to the cooling of hydrous magma chambers. The essential chemical requirement for gold transport to low temperatures is an initial excess of sulfide over Fe in the magmatic fluid, which is best achieved by condensing out Fe-rich brine from a buoyant, low- to medium-salinity vapor enriched in volatile S. This vapor can contract directly to an aqueous liquid, by cooling at elevated pressure above the critical curve of the salt-water fluid system. Physical and chemical conditions are matched when magmatic fluid is released through a gradually downward-retracting interface of crystallizing magma beneath a porphyry stock, predicting the consistent zoning and overprinting relations of alteration and mineralization observed in magmatic hydrothermal systems.

Original languageEnglish
Pages (from-to)761-764
Number of pages4
JournalGeology
Volume32
Issue number9
DOIs
Publication statusPublished - Sept 2004

Other keywords

  • Brine
  • Epithermal
  • Gold solubility
  • Magmatic deposits
  • Porphyry
  • Thermodynamic modeling
  • Vapor

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