TY - JOUR
T1 - Pyrite-sulfosalt reactions and semimetal fractionation in the Chinkuashih, Taiwan, copper-gold deposit
T2 - A 1Ma paleo-fumarole
AU - Henley, R. W.
AU - Berger, B. R.
PY - 2012/8
Y1 - 2012/8
N2 - The mineralized fracture system that underlay paleo-fumarole field at Chinkuashih, Taiwan has been exposed by copper-gold mining to depths of about 550m below the paleo-surface. Its mineralogy and systematic variations in metal and semimetal (Fe, Cu, As, Sb, Bi, Hg, Cd, Sn, Zn, Pb, Se, Te, Au, Ag) concentrations provide insights into the chemical responses of a magmatic-vapor phase as it expands through fracture arrays to the surface and discharges as fumaroles associated with more extensive solfatara. At Chinkuashih, following initial sealing of the fractures by silica-alunite alteration, brittle failure reestablished discharge from an underlying reservoir of magmatic vapor. Crystalline pyrite was deposited first in the fractures and was succeeded and replaced by 'enargite' (Cu 3(As,Sb)S 4) as sulfosalt encrustations ('sublimate') on fracture surfaces and in extensional cracks. Subsequent recrystallization resulted in complex exsolution intergrowths with antimony fractionation to the evolving crystal-vapor interface. Heavy metal fractionation between sulfosalt and vapor enriched the vapor phase in heavy metals that subsequently precipitated as complex Bi-Hg-Sn sulfosalts in discrete areas (paleo-fumaroles) close to the paleo-surface in a manner analogous to modern-day fumaroles on active volcanoes such as Vulcano, Italy. As in similar paleo-fumaroles (e.g., El Indio, Chile and Lepanto, Philippines), the most characteristic reaction sequence is the partial replacement of the early pyrite by enargite and Fe-tennantite. It is proposed that this reaction tracks the decrease in the pressure of the underlying magmatic-vapor reservoir because of the sustained discharge of vapor to the surface.
AB - The mineralized fracture system that underlay paleo-fumarole field at Chinkuashih, Taiwan has been exposed by copper-gold mining to depths of about 550m below the paleo-surface. Its mineralogy and systematic variations in metal and semimetal (Fe, Cu, As, Sb, Bi, Hg, Cd, Sn, Zn, Pb, Se, Te, Au, Ag) concentrations provide insights into the chemical responses of a magmatic-vapor phase as it expands through fracture arrays to the surface and discharges as fumaroles associated with more extensive solfatara. At Chinkuashih, following initial sealing of the fractures by silica-alunite alteration, brittle failure reestablished discharge from an underlying reservoir of magmatic vapor. Crystalline pyrite was deposited first in the fractures and was succeeded and replaced by 'enargite' (Cu 3(As,Sb)S 4) as sulfosalt encrustations ('sublimate') on fracture surfaces and in extensional cracks. Subsequent recrystallization resulted in complex exsolution intergrowths with antimony fractionation to the evolving crystal-vapor interface. Heavy metal fractionation between sulfosalt and vapor enriched the vapor phase in heavy metals that subsequently precipitated as complex Bi-Hg-Sn sulfosalts in discrete areas (paleo-fumaroles) close to the paleo-surface in a manner analogous to modern-day fumaroles on active volcanoes such as Vulcano, Italy. As in similar paleo-fumaroles (e.g., El Indio, Chile and Lepanto, Philippines), the most characteristic reaction sequence is the partial replacement of the early pyrite by enargite and Fe-tennantite. It is proposed that this reaction tracks the decrease in the pressure of the underlying magmatic-vapor reservoir because of the sustained discharge of vapor to the surface.
KW - Arsenic
KW - Copper
KW - Enargite
KW - Fumarole
KW - Gold
KW - High-sulfidation
KW - Magmatic vapor
KW - Solfatara
UR - http://www.scopus.com/inward/record.url?scp=84865292924&partnerID=8YFLogxK
U2 - 10.1111/j.1468-8123.2012.00367.x
DO - 10.1111/j.1468-8123.2012.00367.x
M3 - Article
SN - 1468-8115
VL - 12
SP - 245
EP - 260
JO - Geofluids
JF - Geofluids
IS - 3
ER -