Gold ore-forming fluids of the Tanami region, Northern Australia (original) (raw)

Abstract

Fluid inclusion studies have been carried out on major gold deposits and prospects in the Tanami region to determine the compositions of the associated fluids and the processes responsible for gold mineralization. Pre-ore, milky quartz veins contain only two-phase aqueous inclusions with salinities ≤19 wt% NaCl eq. and homogenization temperatures that range from 110 to 410°C. In contrast, the ore-bearing veins typically contain low to moderate salinity (<14 wt% NaCl eq.), H2O + CO2 ± CH4 ± N2-bearing fluids. The CO2-bearing inclusions coexist with two-phase aqueous inclusions that exhibit a wider range of salinities (≤21 wt% NaCl eq.). Post-ore quartz and carbonate veins contain mainly two-phase aqueous inclusions, with a last generation of aqueous inclusions being very CaCl2-rich. Salinities range from 7 to 33 wt% NaCl eq. and homogenization temperatures vary from 62 to 312°C. Gold deposits in the Tanami region are hosted by carbonaceous or iron-rich sedimentary rocks and/or mafic rocks. They formed over a range of depths at temperatures from 200 to 430°C. The Groundrush deposit formed at the greatest temperatures and depths (260–430°C and ≤11 km), whereas deposits in the Tanami goldfield formed at the lowest temperatures (≥200°C) and at the shallowest depths (1.5–5.6 km). There is also evidence in the Tanami goldfield for late-stage isothermal mixing with higher salinity (≤21 wt% NaCl eq.) fluids at temperatures between 100 and 200°C. Other deposits (e.g., The Granites, Callie, and Coyote) formed at intermediate depths and at temperatures ranging from 240 to 360°C. All ore fluids contained CO2 ± N2 ± CH4, with the more deeply formed deposits being enriched in CH4 and higher level deposits being enriched in CO2. Fluids from deposits hosted mainly by sedimentary rocks generally contained appreciable quantities of N2. The one exception is the Tanami goldfield, where the quartz veins were dominated by aqueous inclusions with rare CO2-bearing inclusions. Calculated δ 18O values for the ore fluids range from 3.8 to 8.5‰ and the corresponding δD values range from −89 to −37‰. Measured δ 13C values from CO2 extracted from fluid inclusions ranged from −5.1 to −8.4‰. These data indicate a magmatic or mixed magmatic/metamorphic source for the ore fluids in the Tanami region. Interpretation of the fluid inclusion, alteration, and structural data suggests that mineralization may have occurred via a number of processes. Gold occurs in veins associated with brittle fracturing and other dilational structures, but in the larger deposits, there is also an association with iron-rich rocks or carbonaceous sediments, suggesting that both structural and chemical controls are important. The major mineralization process appears to be boiling/effervescence of a gas-rich fluid, which leads to partitioning of H2S into the vapor phase resulting in gold precipitation. However, some deposits also show evidence of desulfidation by fluid–rock interaction and/or reduction of the ore-fluid by fluid mixing. These latter processes are generally more prevalent in the higher crustal-level deposits.

Access this article

Log in via an institution

Subscribe and save

• Get 10 units per month
• Download Article/Chapter or eBook
• 1 Unit = 1 Article or 1 Chapter
• Cancel anytime Subscribe now

Buy Now

Price excludes VAT (USA)
Tax calculation will be finalised during checkout.

Instant access to the full article PDF.

Similar content being viewed by others

References

• Adams GJ (1997) Structural evolution and ore genesis of The Granites gold deposits, Northern Territory. B.Sc.(Hons) Thesis, University of Adelaide. Adelaide, Australia, 210pp
• Bagas L, Huston D, Anderson J (2007) Gold deposits in the Palaeoproterozoic Tanami Group, Western Austarlia. Miner Deposita (in this issue)
• Bakker RJ (1997) Clathrates: Computer programs to calculate fluid inclusion V–X properties using clathrate melting temperatures. Comput Geosci 23:1–18
  Article Google Scholar
• Bodnar RJ, Vityk MO (1994) Applications of fluid inclusions in tectonic reconstruction: microthermometric analysis. In: Izquierdo MG, Suarez AMC, Guevara GM, Vanko D, Viggiano GJC (eds) Fifth biennial Pan-American conference on research on fluid inclusions, Cuernavaca, Mexico, 19–21 May 1994, p 10
• Brincat J (1994) The vein paragenesis and mineralization of the East Bullakitchie mine, The Granites goldfield, Northern Territory. University of Adelaide, Australia, 35pp
• Brown PE, Hagemann SG (1995) MacFlinCor and its application to fluids in Archaean lode–gold deposits. Geochim Cosmochim Acta 59:3943–3952
  Article Google Scholar
• Clayton RN, Mayeda TK (1963) The use of bromine pentafluoride in the extraction of oxygen from oxides and silicates for isotopic analysis. Geochim Cosmochim Acta 27:43–52
  Article Google Scholar
• Clayton RN, O’Neil JR, Mayeda TK (1972) Oxygen isotope exchange between quartz and water. J Geophys Res 77:3057–3067
  Article Google Scholar
• Clayton RN, Golodsmith JR, Mayeda TK (1989) Oxygen isotope fractionation in quartz, albite, anorthite and calcite. Geochim Cosmochim Acta 53:725–733
  Article Google Scholar
• Cooke DR, Simmons SF (2000) Characteristics and genesis of ephemeral gold deposits. In: Hagemann SG, Brown PE (eds) Gold in 2000. Reviews in Economic Geology, vol. 13. Society of Economic Geologists, pp 221–244
• Crispe AJ, Vandenberg LC, Scrimgeour IR (2007) Geological framework of the paleoproterozoic Tanami region, Northern Territory. Miner Deposita (in this issue)
• Duan Z, Moller N, Weare JH (1992) An equation of state for the CH4–CO2–H2O system: II Mixtures from 50 to 1000 C and 0 to 1000 bar. Geochim Cosmochim Acta 56:2619–2631
  Article Google Scholar
• Duan Z, Moller N, Weare JH (1996) A general equation of state for supercritical fluid mixtures and molecular dynamics simulation of mixture PVTX properties. Geochim Cosmochim Acta 1209–1216
• Dubessy J, Audeoud D, Wilkins R, Kosztolanyi C (1982) The use of the Raman microprobe MOLE in the determination of the electrolytes dissolved in the aqueous phase of fluid inclusions. Chem Geol 37:137–150
  Article Google Scholar
• Field CW, Fifarek RH (1985) Light stable-isotope systematics in the epithermal environment. In: Berger BR, Bethke PM (eds) Geology and geochemistry of epithermal systems. Reviews in Economic Geology, vol. 2. Society of Economic Geologists, pp 99–128
• Friedman I (1953) Deuterium content of natural waters and other substances. Geochim Cosmochim Acta 4:89–103
  Article Google Scholar
• Gehrig M, Lentz H, Franck EU (1986) The system water–carbon dioxide–sodium chloride to 773 K and 300 MPa. Ber Bunsenges Phys Chem 90:525–533
  Google Scholar
• Groves DI (1993) The crustal continuum model for late-Archaean lode gold deposits of the Yilgarn block, Western Australia. Miner Depos 28:366–374
  Article Google Scholar
• Guoyi D (1994) A progress report of fluid inclusion and petrology from the Callie deposit, The Granites, NT. North Flinders Exploration Ltd. Internal Report
• Higgins NC (1990) Moderately depleted oxygen isotope composition of waters associated with tin- and tungsten-bearing quartz veins: an evaluation of isotopic models. In: Herbert HK, Ho SE (eds) Stable isotopes and fluid processes in mineralization, vol. 23. University of Western Australia, pp204–214
• Hoefs J (1980) Stable isotope geochemistry. Springer, Berlin Heidelberg New York, 208pp
  Google Scholar
• Holloway JR (1984) Graphite–CH4–H2O–CO2 equilibria at low-grade metamorphic conditions. Geology 12:455–458
  Article Google Scholar
• Huston DL, Wygralak AS, Mernagh TP, Vandenberg LC, Crispe AJ, Lambeck L, Cross A, Fraser GL, Williams NC, Worden K, Meixner A (2007) Lode gold mineral system(s) of the Tanami Region, northern Australia. Miner Deposita (in this issue)
• Mernagh TP, Witt WK (1994) Early, methane-rich fluids and their role in Archaean gold mineralization at the Sand King and Missouri deposits, Eastern Goldfields Province, Western Australia. AGSO J Aust Geol Geophys 15:297–312
  Google Scholar
• Mernagh TP, Bastrakov EN, Wyborn LAI (2005) A comparison of some chemical processes of ore precipitation in orogenic and intrusion-related gold mineral systems. structure, tectonics and ore mineralisation processes (STOMP). Abstracts Volume, EGRU Contribution No. 64, p.89
• Morrison G, Guoyi D, England D (1994) A reconnaissance of alteration and mineralisation petrology and fluid inclusions from the Callie deposit, The Granites, NT. North Flinders Exploration Ltd. Internal Report
• Naden J, Shepherd TJ (1989) Role of methane and carbon dioxide in gold deposition. Nature 342:793–795
  Article Google Scholar
• Ridley JR, Diamond LW (2000) Fluid chemistry of orogenic lode gold deposits and implications for genetic models. In: Hagemann SG, Brown PE (eds) Gold in 2000. Reviews in Economic Geology, vol. 13. Society of Economic Geologists, pp 141–162
• Roedder E (1984) Fluid inclusions. In: Ribbe PH (ed) Reviews in mineralogy, vol.12. Mineralogical Society of America, 644pp
• Schmidt C, Bodnar RJ (2000) Synthetic fluid inclusions: XVI. PVTX properties in the system H2O–NaCl–CO2 at elevated temperatures, pressures, and salinities. Geochim Cosmochim Acta 64:3853–3869
  Article Google Scholar
• Scrimgeour I, Sandiford M (1993) Early Proterozoic metamorphism at the Granites gold mine, Northern Territory: implications for the timing of fluid production in high-temperature, low-pressure terranes. Econ Geol 88:1099–1113
  Article Google Scholar
• Sibson RH, Robert F, Poulson KH (1988) High-angle reverse faults, fluid pressure cycling and mesothermal gold–quartz deposits. Geology 16:551–555
  Article Google Scholar
• Smith JB (2000) NTGS-AGSO Geochronology Project Report 3. Australian Geological Survey Organisation Professional Opinion 2000/27. Australian Geological Survey, Canberra, Australia
• Smith MEH, Lovett DR, Pring PI, Sando BG (1998) Dead Bullock Soak gold deposits. In: Berkman DA, Mackenzie DH (eds) Geology of Australian and Papua New Guinean mineral deposits, The Australasian Institute of Mining and Metallurgy, Melbourne, pp 449–460
• Tanami Gold NL (2003) Coyote gold project, media release. 23 December 2003, 6pp
• Tanami Gold NL (2005) High grade resource increase at Coyote. Quarterly report, 7 February 2005, 4pp
• Taylor BE (1987) Stable isotope geochemistry of ore-forming fluids. In: Kyser TK (ed) Short course in stable isotope geochemistry of low temperature fluids, vol. 13. Mineralogical Association of Canada, pp 337–452
• Thomas AV, Spooner ETC (1988) Fluid inclusions in the system H2O–CH4–NaCl–CO2 from metasomatic tourmaline within the border unit of the Tanco zoned granitic pegmatite. Geochim Cosmochim Acta 52:1065–1075
  Article Google Scholar
• Tunks AJ (1996) Geology of the Tanami Gold Mine, Northern Territory. Ph.D. Thesis, University of Tasmania, Hobart, Australia, 239pp
• Tunks AJ, Cooke DR (2007) Geological and structural controls on mineralization of the Tanami gold mine. Miner Deposita (in this issue)
• Vandenberg LC, Hendrickx MA, Crispe AJ, Slater KR, Dean AA (2001) Structural geology of the Tanami Region. Northern Territory Geological Survey, Record 2001–004, 20 pp
• Williams NC (2007) Controls on mineralisation at the world-class Callie gold deposit, Tanami desert, Northern Territory, Australia. Miner Deposita (in this issue)
• Wopenka B, Pasteris JD (1987) Raman intensities and detection limits of geochemically relevant gas mixtures for a laser Raman microprobe. Anal Chem 59:2165–2170
  Article Google Scholar
• Wygralak AS, Mernagh TP (2001) Gold mineralization of the Tanami region. Northern Territory Geological Survey, Record 2001–011, 40 pp
• Wygralak AS, Mernagh TP, Huston DL, Ahmad M (2005) Mineral gold system of the Tanami region. Northern Territory Geological Survey, Report 2004-18
• Ziegenbeim D, Johannes W (1980) Graphite in C–H–O fluids: an unsuitable compound to buffer fluid composition at temperatures up to 700C. Neues Jahrb Mineral Abh 7:289–305
  Google Scholar

Download references

Acknowledgements

The authors wish to thank Newmont Australia Ltd., Tanami Gold, and Anglogold Australasia Ltd, for access to their deposits and drillcore and for assistance while in the field. We are especially grateful to Susan Golding (University of Queensland) for the hydrogen, oxygen, and carbon isotopic analysis. Richard Goldfarb, Philip Brown, Larryn Diamond, David Huston and Subhash Jaireth are thanked for constructive suggestions and comments on earlier drafts of this manuscript. TPM publishes with the permission of the Chief Executive Officer of Geoscience Australia.

Author information

Authors and Affiliations

1. Geoscience Australia, GPO Box 378, Canberra, 2601, Australia
   Terrence P. Mernagh
2. Northern Territory Geological Survey, GPO Box 2901, Darwin, 0801, Australia
   Andrew S. Wygralak

Authors

1. Terrence P. Mernagh
   You can also search for this author inPubMed Google Scholar
2. Andrew S. Wygralak
   You can also search for this author inPubMed Google Scholar

Corresponding author

Correspondence toTerrence P. Mernagh.

Additional information

Editorial handling: D. Huston

Appendix

Appendix

Table 5 Deposit location and description of samples collected for fluid inclusion analysis

Full size table

Rights and permissions

About this article

Cite this article

Mernagh, T.P., Wygralak, A.S. Gold ore-forming fluids of the Tanami region, Northern Australia.Miner Deposita 42, 145–173 (2007). https://doi.org/10.1007/s00126-006-0098-y

Download citation

• Received: 01 January 2006
• Accepted: 05 September 2006
• Published: 07 December 2006
• Issue Date: January 2007
• DOI: https://doi.org/10.1007/s00126-006-0098-y

Keywords