1887
25th International Conference and Exhibition – Interpreting the Past, Discovering the Future
  • ISSN: 2202-0586
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Abstract

An increase in demand for commodities coupled with a decrease in world-class ore deposit discoveries in the last three decades is the driving force for exploring for a new generation of world-class ore deposits at depth. Exploration through cover is becoming one of the critical challenges for the mineral exploration industry.

This paper explores methods of integrating geophysical, geological and landscape data so as to reduce uncertainty in landscape evolution models interpreted from inversion of electromagnetic (EM) data. Inversion of EM data is, in general, non-unique: many different models will be able to fit the EM data equally well, resulting in large uncertainty. However, EM model uncertainty can be significantly constrained when geological and landscape context are taken into account. This study aims to characterise the regolith (weathered and transported cover), and understand how its conductivity varies with the landscape and with the regolith architecture. This is assisted by logging information from 104 boreholes penetrating through the regolith and into the basement rocks. The study area is associated with the DeGrussa Cu-Au deposit located in the Capricorn Orogen of Western Australia, a regolith-dominated terrain where the regolith varies in thickness between <5 and ~150m.

We first select EM decay curves, extracted from an airborne EM survey, whose locations are close to those of the boreholes. We then use a layered-earth (1D) forward model, and invert those data for the electrical resistivities of each of the lithologies identified on the geological borehole logs. Layer boundary depths are fixed to the borehole depths. We show how the non-uniqueness associated with EM inversion can be reduced by the inclusion of decay curves from geology with different layer thickness ratios.

Lithological models derived from the integration of electromagnetic, geological and landscape data show less uncertainty and are therefore more reliable for mineral exploration targeting.

© 2016 ASEG
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/content/journals/10.1071/ASEG2016ab297
2016-12-01
2026-01-14

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References

  1. Anand, R.R., Butt, C.R.M., 2010. A guide for mineral exploration through the regolith in the Yilgarn Craton, Western Australia. Australian Journal of Earth Sciences 57, 1015-1114.
  2. Gonzalez-Alvarez, Salama, W., Ibrahimi, T., LeGras, M., 2015. Geochemical dispersion of the DeGrussa deposit within its associated palaeodrainage system. CSIRO, Mineral Resources, Western Australia, EP 158718, 87.
  3. Gonzalez-Alvarez, I., Boni, M., Anand, R.R., 2016a. Mineral Exploration in Regolith-Dominated Terrains. Global considerations and challenges. Ore Geology Reviews Special Issue 73, 375-379.
  4. Gonzalez-Alvarez, I., Ley-Cooper, Y., Salama, W., 2016b. A geological assessment of airborne electromagnetics for mineral exploration through deeply weathered profiles: the southeast Yilgarn cratonic margin, Western Australia. Ore Geology Reviews
  5. Special Issue 73, 522-539.
  6. Jones, E., Oliphant, E., Peterson, P., 2001. SciPy: Open Source Scientific Tools for Python [WWW Document]. www.scipy.org. URL (accessed 3.7.16).
  7. Munday, T.J., 2009. Regolith Geophysics, in: Scott, K., Pain, C. (Eds.), Regolith Science. pp. 219-247.
  8. Munday, T.J., Macnae, J., Bishop, J., Sattel, D., 2001. A geological interpretation of observed electrical structures in the regolith: Lawlers, Western Australia. Explor. Geophys. 32, 36-17. doi:10.1071/EG01036
  9. Palacky, G.V., 1988. Resistivity characteristics of geologic targets, in: Nabighian, M.N. (Ed.), Electromagnetic Methods in Applied Geophysics. Electromagnetic methods in applied geophysics.
  10. Raiche, A., Sugeng, F., Wilson, G., 2007. Practical 3D EM inversion - the P223F software suite. ASEG Extended Abstracts 2007, 1. doi:10.1071/ASEG2007ab114
  11. Tarantola, A., 1987. Inverse Problem Theory: Methods for data fitting and model parameter estimation, Book.
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  • Article Type: Research Article
Keyword(s): electromagnetics; inversion; mineral exploration; regolith.

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