1887
ASEG2006 - 18th Geophysical Conference
  • ISSN: 2202-0586
  • E-ISSN:

Abstract

Isa Superbasin strata in the Lawn Hill Platform host major base metal sulfide mineralization including the giant Century Zn-Pb deposit. Mineral paragenesis, organic maturation, K-Ar dating and stable isotope studies demonstrate that long-lived structures such as the Termite Range Fault acted as hot fluid conduits several times during the Paleoproterozoic and Mesoproterozoic. K-Ar dating of illites, in combination with other datasets, may identify three thermal events in the Lawn Hill Platform at 1500, 1440-1400 and 1250-1150 Ma. 1500 Ma is a Late fcan Orogeny age recorded only in the south that may reflect exhumation of a provenance region. The 1440-1300 Ma ages are related to fault reactivation and a thermal/?fluid pulse at ~1440-1400 Ma, with subsequent enhanced cooling. The youngest thermal/fluid flow event at 1250-1150 Ma is recorded mainly in the northeast and is probably related to the assembly of Rodinia.

An extensive carbonate alteration halo in the footwall of the circa 1575 Ma Century Zn-Pb deposit extends some 15 km along strike. Calculations of fluid oxygen and carbon isotope composition based on model temperatures of 120°C for the ore zone siderites and 180°C for siderites and ankerites in the regional carbonate alteration halo indicate similar ore and alteration fluid compositions (°18O = 3 to 10 per mil; °13C = -7 to -3 per mil). This fluid isotope composition is consistent with highly evolved basinal brines and mixed inorganic and organic carbon sources. The good agreement between maximum temperature estimates from illite crystallinity and organic reflectance and inverse correlation with carbonate oxygen isotopes in northeast Lawn Hill platform boreholes indicate thermal maturation and carbonate formation resulted from interaction with the 1250-1150 Ma fluids. The calculated fluid isotope compositions are consistent with an evolved basinal brine (°18O = 5.1 to 9.4 per mil V-SMOW; °13C = -13.2 to -3.7 per mil V-PDB) that contained a significant organic carbon component. Differences in carbon and oxygen isotope systematics of alteration carbonate are significant to their use with lithogeochemical vectors in mineral exploration in the northern Australian basins.

© ASEG 2006
Loading

Article metrics loading...

/content/journals/10.1071/ASEG2006ab052
2006-12-01
2026-01-16

  • From This Site

    /content/journals/10.1071/ASEG2006ab052
    dcterms_title,dcterms_subject,pub_keyword
    -contentType:Journal -contentType:Contributor -contentType:Concept -contentType:Institution
    10
    5
Loading full text...

Full text loading...

References

  1. Abbott, S.T., and Sweet, I.P., 2000, Tectonic origin of third order sequences in a siliciclastic ramp-style basin: an example from the Roper Superbasin (Mesoproterozoic), northern Australia: Australian Journal of Earth Sciences 47, 637-657.
  2. Árkai, P., 1991, Chlorite crystallinity: an empirical approach and correlation with illite crystallinity, coal rank and mineral facies as exemplified by Palaeozoic and Mesozoic rocks of northeast Hungary: Journal of Metamorphic Geology 9, 723-734.
  3. Bechtel, A, Puttmann, W., and Hoernes, S., 1995, Reconstruction of the thermal history of the Kupferschiefer within the Zechstein basin of central Europe: a stable isotope and organic geochemical approach: Ore Geology Reviews 9, 371-389.
  4. Broadbent, G.C., Myers, R.E., and Wright, J.V., 1998, Geology and origin of shale-hosted Zn-Pb-Ag mineralization at the Century deposit, northwest Queensland, Australia: Economic Geology 93, 1264-1294.
  5. Carr, G.R., Sun, S-S., Page R.W. and Hinman, M., 1996, Recent developments in the use of lead isotope model ages in Proterozoic terrains, in Baker, T., Rotherham, J., Richmond, J., Mark, G., and Williams, P., eds., MIC’96: New Developments in Metallogenic Research: The McArthur, Mt Isa, Cloncurry Minerals Province: Townsville, Economic Geology Research Unit Contribution 55, 99-103.
  6. Clayton, R.N., and Mayeda, T.K., 1963, The use of bromine pentafluoride in the extraction of oxygen from oxides and silicates for isotopie analysis: Geochimica et Cosmochimica Acta 27, 43-52.
  7. Coleman, M.L., Shepherd, T.J., Durham, J.J., Rouse, J.E., and Moore, G.R., 1982, Reduction of water with zinc for hydrogen isotope analysis: Analytical Chemistry 54, 993-995.
  8. Golding, S.D., Uysal, I.T., Glikson, M., Baublys, K.A, and Southgate, P.N., 2006, Timing and chemistry of fluid flow events in the Lawn Hill Platform, northern Australia: Economic Geology, in press.
  9. Hitzman, M.W., and Beaty, D.W., 1996, The Irish Zn-Pb-(Ba) Orefield, in Williams, P.J., ed., Carbonate-Hosted Lead-Zinc deposits: Society of Economic Geologists Special Publication 4,112-143.
  10. Kotzer, T.G., and Kyser, T.K., 1995, Petrogenesis of the Proterozoic Athabasca Basin, northern Saskatchewan, Canada, and its relation to diagenesis, hydrothermal uranium mineralisation and paleohydrology: Chemical Geology 120, 45-89.
  11. KÁbler, B., 1964, Les argiles, indicateurs de metamorphisme: Rev Inst Fr Petrol 1, 1093-1112.
  12. Kyser, T.K., and Kerrich, R., 1990, Geochemistry of fluids in tectonically active crustal regions, in Nesbitt, B.E., ed., Fluids in Tectonically Active Fluid regimes of the Continental Crust: Mineralogical Association of Canada Short Course 18, 133-230.
  13. Large, R.R., and McGoldrick, P.J., 1998, Lithogeochemical halos and geochemical vectors to stratiform sediment hosted Zn-Pb-Ag deposits. Part 1: Lady Loretta deposit, Queensland: Journal of Geochemical Exploration 63, 37-56.
  14. Large, R.R., Bull, S.W., Cooke, D.R., and McGoldrick, P.J., 1998, A genetic model for the HYC deposit, Australia: based on regional sedimentology, geochemistry and sulfide-sediment relationships: Economic Geology 93, 1345-1368.
  15. Large, R.R., Bull, S.W., and Winefield, P.R., 2001, Carbon and oxygen isotope halo in carbonates related to the McArthur River (HYC) Zn-Pb-Ag deposit, north Australia: implications for sedimentation, ore genesis and mineral exploration: Economic Geology 96, 1567-1593.
  16. McCrea, J.M., 1950, On the isotopie composition of carbonates and a paleotemperature scale: Journal of Chemical Physics, v. 18, p. 849-857.
  17. Odin, G.S. and 35 collaborators, 1982, Interlaboratory standards for dating purposes, in Odin, G.S., ed., Numerical Dating in Stratigraphy: John Wiley, New York, 123-149.
  18. Southgate, P.N., Bradshaw, B.E., Domagla, J., Idnurm, M., Krassy, A.A., Page, R.W., Sami, T.T., Scott, D.L., Lindsay, J.F., McConachie, B.M., and Tarlowski, C, 2000, Chronostratigraphic framework for Palaeoproterozoic rocks (1730-1575Ma) in northern Australia and implications for base metal mineralization: Australian Journal of Earth Sciences 47, 461-483.
  19. Steiger, R.H., and Jager, E., 1977, Subcommission on geochronology: convention on the use of decay constants in geochronology and cosmochronology: Earth and Planetary Science Letters 36, 359-362.
  20. Taylor, B.E., 1987, Stable isotope geochemistry of ore-forming fluids, in Kyser, T.K., ed., Short Course in Stable Isotope Geochemistry of Low Temperature Fluids: Mineral association Canada 13, 337-445.
  21. Uysal, I.T., Glikson, M., Golding, S.D., and Audsley, F., 2000a, The thermal history of the Bowen Basin, Queensland, Australia: vitrinite reflectance and clay mineralogy of Late Permian coal measures: Tectonophysics 323, 105-109.
  22. Uysal, I.T., Golding, S.D., and Baublys, K., 2000b, Stable isotope geochemistry of authigenic clay minerals from Late Permian coal measures, Queensland, Australia: implications for the evolution of the Bowen Basin: Earth and Planetary Science Letters 180, 149-162.
  23. Uysal, I.T., Golding, S.D., and Glikson, M., 2000c, Petrographic and isotope constraints on the origin of authigenic carbonate minerals and the associated fluid evolution in Late Permian coal measures, Bowen Basin (Queensland), Australia: Sedimentary Geology 136, 189-206.
  24. Uysal, I.T., Glikson, M., Golding, S.D., and Southgate, P.N., 2004, Hydrothermal control on organic matter alteration and illite precipitation, Mt Isa Basin, Australia: Geofluids 4, 131-142.
  25. Yang, C, and Hesse, R., 1991, Clay minerals as indicators of diagenetic and anchimetamorphic grade in an overthrust belt, external domain of southern Canadian Appalachians: Clay Minerals 26, 211-231.
  26. Zwingmann, H., Clauer, N., and Gaupp, R., 1999, Structure-related geochemical (REE) and isotopie (K-Ar, Rb-Sr, δ18O) characteristics of clay minerals from Rotliegend sandstone reservoirs (Permian, northern Germany): Geochimica et Cosmochimica Acta 63, 2805-2823.
/content/journals/10.1071/ASEG2006ab052
Loading
  • Article Type: Research Article
Keyword(s): age dating; fluid flow; mineral exploration; stable isotopes; thermal history; Zn-Pb deposits

Most Cited This Month Most Cited RSS feed

This is a required field
Please enter a valid email address
Approval was a Success
Invalid data
An Error Occurred
Approval was partially successful, following selected items could not be processed due to error