Fluid and mass transfer during metabasalt alteration and copper mineralization at Mount Isa, Australia
CA Heinrich, JHC Bain, TP Mernagh… - Economic …, 1995 - pubs.geoscienceworld.org
Economic Geology, 1995•pubs.geoscienceworld.org
Metabasalts surrounding the metasediment-hosted base metal deposit at Mount Isa have
been modified by metamorphism, polyphase deformation, and several stages of
hydrothermal alteration. This study aims to understand the large-scale hydrothermal
processes that determined the chemical composition of syn to postmetamorphic ore brines,
prior to being focused into chemicaly anomalous metasediments that acted as a chemical
trap for localized copper precipitation. Field mapping of the metabasalts provided the …
been modified by metamorphism, polyphase deformation, and several stages of
hydrothermal alteration. This study aims to understand the large-scale hydrothermal
processes that determined the chemical composition of syn to postmetamorphic ore brines,
prior to being focused into chemicaly anomalous metasediments that acted as a chemical
trap for localized copper precipitation. Field mapping of the metabasalts provided the …
Abstract
Metabasalts surrounding the metasediment-hosted base metal deposit at Mount Isa have been modified by metamorphism, polyphase deformation, and several stages of hydrothermal alteration. This study aims to understand the large-scale hydrothermal processes that determined the chemical composition of syn to postmetamorphic ore brines, prior to being focused into chemicaly anomalous metasediments that acted as a chemical trap for localized copper precipitation. Field mapping of the metabasalts provided the framework to determine the relative timing of district-scale alteration events, which were then studied by mineralogic observations and bulk mass balance measurements. Microthermometry, Raman microspeetrometry and Br/Cl analyses of fluid inclusions, and H, O, C, and S stable isotope measurements on vein minerals were used to characterize the hydrothermal fluids associated with the alteration events. All fluids are moderately to highly saline, variably Ca enriched with high Br/Cl compared to modern seawater, and isotopiealy most akin to modern evolved basin or low-grade metamorphic brines. The timing and fluid-tracer observations in conjunction with thermodynamic mass transfer modeling permit the following correlation between district-scale alteration processes and the mine-scale hydrothermal events associated with copper deposition at Mount Isa.District-scale epidote-sphene alteration of metabasalts temporally overlapped with the peak of greenschist facies metamorphism and deformation and is widely distributed in flow-top breccias and as halos around synmetamorphic quartz-calcite veins. It is associated with calcic brines with 12 to 38 wt percent CaCl 2 + NaCl equiv, and thermodynamic modeling suggests that the observed mineralogy and bulk mass changes can be explained by focusing of metabasalt-equilibrated fluids and by reaction with similar rocks at somewhat higher temperature. Similar timing and fluid characteristics are associated with dolomitic alteration at the Mount Isa mine, where mixing of metabasalt-derived calcic brine with metamorphic CO 2 from the metasediments led to massive dolomite precipitation.Kilometer-scale fracture zones associated with carbonate-Fe oxide alteration (calcite + albite + magnetite + or - hematite + or - biotite + or - chlorite) cut all penetrative foliations in the metabasalts east of Mount Isa. They are locally associated with uranium mineralization and are characterized by medium-salinity NaCl-rich fluid inclusions (8-93 wt % NaCl equiv). Carbonate-Fe oxide alteration is interpreted to mark channelways of infiltration by oxidized (sulfate-bearing) brines from outside the metabasalt sequence, possibly from an overlying evaporitic cover sequence. Fluid characteristics, evidence for extreme copper mobility, and timing criteria of alteration relative to deformation suggest a temporal, and possibly genetic, correlation with the main copper and silica deposition stage at the Mount Isa mine.Mg chlorite-rutile alteration is restricted to metabasalts immediately below the copper deposit and the vicinity of the Mount Isa fault zone, where higher grade amphibolite facies metabasalts were upthrust against the greenschist facies metabasalts and metasediments now hosting the copper ore bodies. Mg chlorite-rutile alteration of metabasalts, and copper mineralization in the adjacent reduced sediments, can both be explained by fluid focusing along an actively extending contact zone between the oxidized metabasalts and the reducedmetasediments. The brines focused into this contact zone were initially oxidized as a result of infiltration through the carbonate-Fe oxide fracture zones and less altered …
GeoScienceWorld