Metal complexation and ion hydration in low density hydrothermal fluids: Ab initio molecular dynamics simulation of Cu(I) and Au(I) in chloride solutions (25-1000 degrees C, 1-5000 bar)

Yuan Mei, Weihua Liu, David M. Sherman, Joel Brugger*

*Corresponding author for this work

Research output: Contribution to journalArticle (Academic Journal)peer-review

73 Citations (Scopus)

Abstract

Low-density supercritical fluids are suspected of being able to transport metals, but it is unclear what the speciation/complexation would be in such conditions. In this work, we used ab initio molecular dynamics simulations to investigate the complexation, ion association and hydration of Cu+ and Au+ in NaCl brines as a function of solution density, from ambient to supercritical conditions (to 1000 degrees C, 5000 bar). Cu(I) and Au(I) form distorted linear complexes with two chloride ligands (i.e., CuCl2- and AuCl2-) in subcritical chloride brines. We have discovered that these charged complexes remain in high density supercritical fluids even at high temperature; however, with decreasing density, these complexes become progressively neutralized by ion association with Na+ to form low-charge (NanCuCl2)(n-1) and (NanAuCl2)(n-1) complexes. In these species, the Na+ ion is very weakly bonded in the outer coordination sphere, resulting in highly disordered structures and fast (few pico-seconds) exchange among coordinated and solvent Na+ ions. Thermodynamic models to predict the solubility of metals in low-density magmatic or metamorphic fluids must account for these species. In addition, we found that the number of water molecules (i.e., the hydration number) surrounding the Cu+, Au+, Na+ and Cl- ions decreases linearly when fluid density decreases; this supports empirical thermodynamic models that correlate the stability constants of complexation reactions with solvent density. The traditional Born-model description explains the ion association as resulting from the decreased dielectric constant of the solvent. However at a molecular level, the increased ion association results from the increase in translational entropy associated with ion dehydration. (C) 2014 Elsevier Ltd. All rights reserved.

Original languageEnglish
Pages (from-to)196-212
Number of pages17
JournalGeochimica et Cosmochimica Acta
Volume131
DOIs
Publication statusPublished - 15 Apr 2014

Keywords

  • RAY-ABSORPTION SPECTROSCOPY
  • IN-SITU XAS
  • WATER-VAPOR
  • ELEVATED-TEMPERATURES
  • THERMODYNAMIC PROPERTIES
  • SUPERCRITICAL CONDITIONS
  • COORDINATION STRUCTURE
  • SODIUM-CHLORIDE
  • SYSTEM H2O-NACL
  • FINE-STRUCTURE

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