Quick Search:    advanced search

GSW Home   GeoRef Home   My GSW Alerts   Contact GSW   About GSW   Journals List   Help

This Article Figures Only Full Text Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in Web of Science Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Web of Science (10) Citing Articles via Google Scholar Google Scholar Articles by Doyle, M. G. Search for Related Content GeoRef GeoRef Citation

Volcanic Influences on Hydrothermal and Diagenetic Alteration: Evidence from Highway-Reward, Mount Windsor Subprovince, Australia

Mark G. Doyle^,*

Centre for Ore Deposit Research, University of Tasmania, Hobart, Tasmania 7001, Australia

E-mail, mdoyle{at}cgm.uwa.edu.au

Synvolcanic sills and cryptodomes hosting the Highway-Reward volcanic-hosted massive sulfide deposit invaded wet, poorly consolidated silt, sand, and pumice breccia. Margins of the porphyritic units display perlitic and quench fractures suggesting that they were formerly glassy. Interiors of the rhyolites, rhyodacites, and dacites were originally glassy, partly glassy, or comprised crystalline domains exhibiting spherulitic, lithophysae, and micropoikilitic textures. No glass is preserved and the sills and cryptodomes are now completely crystalline. Primary devitrification structures crystallized early above the glass transition temperature and before the formation of perlite or quench fractures. Crystallization of residual glass proceeded by diagenetic alteration, volcanic-associated hydrothermal alteration, and ore-associated hydrothermal alteration.

Massive sulfide ore is enclosed in a discordant alteration envelope that extends at least 60 m above ore and is known to a depth of 150 m in the footwall. In general, there is a progression from central quartz-sericite ± pyrite zones, giving way to zones of chlorite ± anhydrite ± gypsum, chlorite-sericite-quartz, and finally chlorite-sericite distal to ore. The outermost alteration grades into lithofacies that have altered to various background assemblages of feldspar, hematite, sericite, chlorite, quartz, epidote, and carbonate.

Compared to least altered lithofacies, the quartz-sericite ± pyrite zones are enriched in SiO₂, K₂O, Fe₂O₃, S, and Ba, and depleted in Na₂O, CaO, MgO, and Sr. Elevated concentrations of MgO, Fe₂O_3, and S, coupled with low Na₂O, CaO, and K₂O values, characterize chloritized zones. The pattern of low Na₂O, CaO, and MgO values and high K₂O values passing outward through the chlorite-sericite ± quartz zones is more erratic. The Ishikawa alteration index (AI) value and the chlorite-carbonate-pyrite index (CCPI) value become progressively larger passing from background-altered facies (AI <60; CCPI = 20–55) into the footwall and hanging-wall alteration zones (AI = 89–97; CCPI = 41–99). At AI values greater than 90, Cu, Bi, and Mo are elevated. The S/Na₂O ratio increases toward ore, whereas Sr/Ba ratios are lowest at AI values above 90. The geochemical halo patterns reflect the composite response of lithofacies to mineralogical and textural changes accompanying diagenetic alteration, volcanic-associated hydrothermal alteration, and ore-associated hydrothermal alteration.

Most alteration zones around ore display two or more overprinting alteration mineral assemblages. Within single alteration zones, the distribution of alteration minerals and assemblages varies spatially in response to contrasting lithofacies character. Formerly glassy coherent and volcaniclastic facies display mineralogical and textural changes that reflect the influence of fracture (perlitic, quench) and/or matrix permeability and porosity on fluid migration. Crystalline domains of volcanic facies generally preserve their original texture, although recrystallization has partly destroyed primary devitrification microstructures. Alteration minerals are localized along cooling joints, hydraulic fractures, and veins or form mottled, patchy, or wispy domains. In contrast, siltstone that separates intrusions and forms the matrix in peperite is relatively unaltered or was baked during magma-sediment mixing.

In zones of intense quartz-sericite ± pyrite, chlorite ± anhydrite ± gypsum, and sericite alteration, high water/rock ratios, an extended history of fluid flow, and elevated temperatures promoted large-scale mobilization of elements in all facies. Relics of the early alteration mineral assemblages are locally preserved in these zones and imply a progression from initial volcanic-determined alteration to hydraulic fracture and vein-controlled alteration as the hydrothermal system intensified.

The distribution of alteration assemblages and ores implies that fluid pathways varied in scale from very large, where the sills and cryptodomes focused hydrothermal fluid flow and mineralization, to very small where volcanic fracture-controlled porosity and permeability localized mineral precipitation.

This article has been cited by other articles:

				G. Giorgetti, T. Monecke, R. Kleeberg, and M. D. Hannington LOW-TEMPERATURE HYDROTHERMAL ALTERATION OF SILICIC GLASS AT THE PACMANUS HYDROTHERMAL VENT FIELD, MANUS BASIN: AN XRD, SEM AND AEM-TEM STUDY Clays and Clay Minerals, April 1, 2006; 54(2): 240 - 251. [Abstract] [Full Text] [PDF]

				R. R. Large, R. R. Large, J. McPhie, J. B. Gemmell, W. Herrmann, and G. J. Davidson The Spectrum of Ore Deposit Types, Volcanic Environments, Alteration Halos, and Related Exploration Vectors in Submarine Volcanic Successions: Some Examples from Australia Economic Geology, August 1, 2001; 96(5): 913 - 938. [Abstract] [Full Text] [PDF]

				R. R. Large, R. R. Large, R. L. Allen, M. D. Blake, and W. Herrmann Hydrothermal Alteration and Volatile Element Halos for the Rosebery K Lens Volcanic-Hosted Massive Sulfide Deposit, Western Tasmania Economic Geology, August 1, 2001; 96(5): 1055 - 1072. [Abstract] [Full Text] [PDF]