1887
1st Australasian Exploration Geoscience Conference – Exploration Innovation Integration
  • ISSN: 2202-0586
  • E-ISSN:
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Abstract

The oxidation of Fe-containing sulfide mineralization can lead to the development of natural galvanic cells that are characterized by a reduced acid chimney above the mineralization itself and pH-redox controlled chemical haloes surrounding the chimney. Such chimneys may extend through overlying transported regolith cover of varying thicknesses and composition, altering regolith mineralogy (changes to clays, loss of carbonates), element distribution patterns and geophysical characteristics such as electrical conductivity (EC). This paper compares EM and geochemical profiles in transported regolith over porphyry style Au-Mo-Cu mineralization at Mandamah (NSW) and MVT style Pb-Zn mineralization at Pitchi (Iran).

At Mandamah, mineralisation is buried under 30 m of residual regolith and a further 50 m of re-weathered alluvium. Mineralised zones that intersect the base of weathering are characterized by low EM and EC in the upper 6 m of the transported regolith profile. This can be related to changes in clay mineralogy and the destruction of carbonates caused by an acid chimney that formed during a “prograde” phase of regolith development. These patterns are also variably reflected in soil pH and the distribution of selectively-extracted Ca, Mg, S, Ba and REE in the upper part of the transported regolith profile, but generally not in the elements of economic interest (Au, Cu or Mo). At Pitch carbonate-hosted Pb-Zn mineralisation is covered by 80 m of barren dolomitic sedimentary rocks and a thin layer of alluvium and colluvium. There is an increase in the EM and EC as well as Na and S in the transported regolith above mineralisation and adjacent low EC values, but again no detectable patterns in the main ore-related metals. The combined geochemical and (EM) geophysical approach provides a new approach to exploration in areas with economically prospective geology but where mineralization is buried by various forms of cover including transported regolith.

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2018-12-01
2026-01-19

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References

  1. Cohen, D.R., Kelley, D.L., Anand, R.R. and Coker, W.B., 2010, Major Advances in Exploration Geochemistry 1998-2007: Geochemistry: Exploration Environment Analysis, 10, 3-16.
  2. Dalrymple, I.J., Cohen, D.R. and Gatehouse, S.G, 2005, Optimisation of partial extraction chemistry for buffered acetate and hydroxylamine leaches: Geochemistry: Exploration, Environment, Analysis, 5, 279-285.
  3. Govett, G.J.S, 1974, Soil conductivities: Assessment of an electrogeochemical exploration technique: Geochemical Exploration 1974, Association of Exploration Geochemists, 101-118.
  4. Govett, G.J.S. and Atherden, P.R., 1987, Electrogeochemical patterns in surface soils: Detection of blind mineralization beneath exotic cover, Thalanga, Queensland, Australia: Journal of Geochemical Exploration, 28, 201-218.
  5. Govett, G.J.S., 1976, Detection of deeply buried and blind sulphide deposits by measurement of H+ and conductivity of closely spaced surface soil samples: Journal of Geochemical Exploration, 6, 359-82.
  6. Hamilton, S.M., 1998, Electrochemical mass-transport in overburden: a new model to account for the formation of selective leach geochemical anomalies in glacial terrain: Journal of Geochemical Exploration, 63, 155-172.
  7. Heberlein, D.R. and Samson H., 2010, Comparative study of partial and selective extractions of soils over blind porphyry copper-gold mineralization at Kwanika and Mount Milligan, central British Columbia (NTS 093N/01,/19): fieldwork, soil conductivity and pH results. Geoscience BC Summary of Activities 2009, Geoscience BC Report, 11-24.
  8. Huang, J., Mokhtari, A.R., Cohen, D.R., Monteiro Santos, F.A. and Triantafilis, J., 2015, Modelling soil salinity across a gilgai landscape by inversion of EM38 and EM31 data: European Journal of Soil Science, 66, 951-960.
  9. Kriege, R., 2004, Determination of interfaces within the regolith using near-surface geophysical and petrographic methods at the Whirling Dervish gold project, Western Australia: I.C. Roach (ed.), Regolith 2004. CRCLEME, Perth.
  10. Mann, A.W., Birrell, R.D., Fedikow, M.A.F. and De Souza, H.A.F., 2005, Vertical ionic migration: mechanisms, soil anomalies, and sampling depth for mineral exploration: Geochemistry - Exploration, Environment, Analysis, 5, 201-210.
  11. Mokhtari, A.R., Cohen, D.R. and Gatehouse S.G., 2009a, Geochemical effects of deeply buried Cu-Au mineralization on transported regolith in an arid terrain: Geochemistry - Exploration, Environment, Analysis, 9, 227-236.
  12. Mokhtari, A.R., Cohen, D.R. and Gatehouse S.G., 2009b, Geophysical support for geochemistry in detecting deeply buried mineralization: a case study from Mandamah, Australia: Explore, 145.
  13. Smee, B.W., 1983, Laboratory and field evidence in support of the electrogeochemically enhanced migration of ions through glaciolacustrine sediment: Journal of Geochemical Exploration, 19, 277-304.
  14. Smee, B.W., 1998, A new theory to explain the formation of soil geochemical responses over deeply covered gold mineralization in arid environments: Journal of Geochemical Exploration, 61, 149-72.
  15. Triantafilis, J., Odeh, I.O.A. and McBratney, A.B., 2001, Five geostatistical models to predict soil salinity from electromagnetic induction data across irrigated cotton: Soil Science Society of America Journal, 65, 869-878.
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  • Article Type: Research Article
Keyword(s): cover; Electrical conductivity; EM; geochemical dispersion

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