Terry Seward
Terry Seward
Professor of Chemistry and Geochemistry, Victoria University of Wellington
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Cited by
Cited by
Thio complexes of gold and the transport of gold in hydrothermal ore solutions
TM Seward
Geochimica et cosmochimica Acta 37 (3), 379-399, 1973
Hydrosulphide complexing of Au (I) in hydrothermal solutions from 150-400 C and 500-1500 bar
LG Benning, TM Seward
Geochimica et Cosmochimica Acta 60 (11), 1849-1871, 1996
Metal transport by hydrothermal ore fluids
TM Seward
Geochemistry of hydrothermal ore deposits, 435-486, 1997
Magmatic vapor contraction and the transport of gold from the porphyry environment to epithermal ore deposits
CA Heinrich, T Driesner, A Stefánsson, TM Seward
Geology 32 (9), 761-764, 2004
Gold (I) complexing in aqueous sulphide solutions to 500 C at 500 bar
A Stefánsson, TM Seward
Geochimica et Cosmochimica Acta 68 (20), 4121-4143, 2004
The transport and deposition of gold in hydrothermal systems
TM Seward
Gold'82: The geology, geochemistry and genesis of gold deposits, 165-181, 1984
Dissolution kinetics of fosteritic olivine at 90-150 C including effects of the presence of CO2
M Hänchen, V Prigiobbe, G Storti, TM Seward, M Mazzotti
Geochimica et cosmochimica acta 70 (17), 4403-4416, 2006
The Rotokawa geothermal system, New Zealand; an active epithermal gold-depositing environment
RE Krupp, TM Seward
Economic Geology 82 (5), 1109-1129, 1987
The stability of chloride complexes of silver in hydrothermal solutions up to 350 C
TM Seward
Geochimica et Cosmochimica Acta 40 (11), 1329-1341, 1976
The Chemistry of Metal Transport and Deposition by Ore-Forming Hydrothermal Fluids
TM Seward, AE Williams-Jones, AA Migdisov
Treatise on Geochemistry (Second Edition), Elsevier, Oxford 13, 29-57, 2014
The adsorption of gold (I) hydrosulphide complexes by iron sulphide surfaces
AM Widler, TM Seward
Geochimica et Cosmochimica Acta 66 (3), 383-402, 2002
The hydrothermal geochemistry of gold
TM Seward
Gold metallogeny and exploration, 37-62, 1991
The hydrothermal chemistry of gold and its implications for ore formation: boiling and conductive cooling as examples
TM Seward
The stability of chlorozinc (II) complexes in hydrothermal solutions up to 350 C
JR Ruaya, TM Seward
Geochimica et Cosmochimica Acta 50 (5), 651-661, 1986
The system hydrogen‐water up to 440 C and 2500 bar pressure
TM Seward, EU Franck
Berichte der Bunsengesellschaft für physikalische Chemie 85 (1), 2-7, 1981
Ore metals in active geothermal systems
BG Weissberg, PRL Brown, S TM
Geochemistry of hydrothermal ore deposits (2nd edition), 738-780, 1979
The stability of hydrosulphido-and sulphido-complexes of Au (I) and Ag (I) at 25 C
PJ Renders, TM Seward
Geochimica et Cosmochimica Acta 53 (2), 245-253, 1989
The formation of lead (II) chloride complexes to 300 C: A spectrophotometric study
TM Seward
Geochimica et Cosmochimica Acta 48 (1), 121-134, 1984
Molecular dynamics simulation study of ionic hydration and ion association in dilute and 1 molal aqueous sodium chloride solutions from ambient to supercritical conditions
T Driesner, TM Seward, IG Tironi
Geochimica et Cosmochimica Acta 62 (18), 3095-3107, 1998
A spectrophotometric study of hydrogen sulphide ionisation in aqueous solutions to 350 C
OM Suleimenov, TM Seward
Geochimica et cosmochimica acta 61 (24), 5187-5198, 1997
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