Electrical Properties of Magnetite- and Hematite-Rich Rocks and Ores

Lisa Vella; Don Emerson

doi:10.1071/ASEG2012ab232

ISSN: 2202-0586
E-ISSN:

oa Electrical Properties of Magnetite- and Hematite-Rich Rocks and Ores
Authors Lisa Vella^a and Don Emerson^b
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^a Teck Australia Pty. Ltd., PO Box 1677 West Perth WA 6872, [email protected] ^b Systems Exploration (NSW) Pty. Ltd., Box 6001 Dural Delivery Centre NSW 2158, [email protected]
Publisher: Australian Society of Exploration Geophysicists
Source: ASEG Extended Abstracts, Volume 2012, Issue ASEG2012 - 22nd Geophysical Conference, Dec 2012, p. 1 - 4
DOI: https://doi.org/10.1071/ASEG2012ab232
- Published online: 01 Dec 2012

Abstract

Summary

Magnetite and hematite are common iron-oxides, being found in sedimentary, metamorphic and igneous environments and being associated with a wide variety of deposits styles, including orogenic gold, iron-oxide copper-gold and iron-ore deposits. While the magnetic and mass properties of magnetite and hematite have been comprehensively studied, there is relatively limited published information on their electrical properties, although anecdotally, it would appear that many geophysicists have encountered the situation in which their ‘highly prospective’ EM or IP anomaly has turned out to be the result of barren magnetite, and/or hematite.

In 1994, Emerson and Yang extensively studied the electrical properties of magnetite-rich rocks as part of AMIRA project P416. Eight sponsor companies contributed a variety of samples for laboratory measurements of mass, magnetic, galvanic electrical, electromagnetic and induced polarisation properties. A petrological study was also carried out. The electrical properties of hematite have been similarly investigated on behalf of individual companies.

This work has demonstrated that sulphide-free, magnetite- and/or hematite-rich rocks can be moderate to good conductors and also exhibit a measurable IP response. And in some cases, electrical anisotropy may be significant. The electrical behaviour of magnetite and hematite is related to factors such as quantity, grain size and texture and their electrical response can be considerably enhanced by relatively small amounts of sulphides, such as chalcopyrite. Field examples are presented confirming laboratory observations.

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References

Carmichael, R.S., 1989, Practical handbook of physical properties of rocks and minerals: CRC Press Inc.
Emerson, D.W. and Yang, Y.P., 1994, Electrical properties of magnetite rich rocks and ores. Unpublished report.
Esdale, D., Pridmore, D.F., Coggon, J., Muir, P., Williams, P. and Fritz, F., 2003, The Olympic Dam copper-uranium-goldsilver- rare earth element deposit, South Australia: A geophysical case study: Geophysical signatures of South Australian mineral deposits, 147-167.
Hart, J. and Freeman, H., 2003, Geophysics of the Prominent Hill prospect, South Australia: Geophysical signatures of South Australian mineral deposits, 93-100.
Ineson, P.R., 1989, Introduction to practical ore microscopy: Longman Group.
Malmqvist, L., 1978, Some applications of IP techniques for different geophysical prospecting purposes: Geophysical Prospecting, 26, 97-121.
Nelson, P.H., and Van Voorhis, G.D., 1983, Estimation of sulphide content from induced polarisation data: Geophysics, 48, 62-75.
Pittard, K. and Bourne. B., 2007, The contribution of magnetite to the induced polarisation response of the Centenary orebody: Exploration Geophysics, 38, 200-207.
Shuey, R.T., 1975, Semiconducting ore minerals: Elsevier Scientific Publishing Company.
Vanhala, H. and Peltoneimi, M., 1992, Spectral IP studies of Finnish ore prospects: Geophysics, 957, 1545-1555.
Vella, L., 1995, Petrophysical characteristics of BIF-hosted gold deposits and the application of down hole EM to their exploration, with examples from Hill 50 Gold Mine, Mt Magnet, WA: Exploration Geophysics, 26, 106-115.
Vella, L. and Emerson, D.W., 2009, Carrapateena: Physical properties of a new iron-oxide copper-gold deposit: 20th International Geophysical Conference and Exhibition, Adelaide, Extended Abstracts, 1-13
Yang, Y.P. and Emerson, D.W., 1997, Electromagnetic conductivities of rock ores: theory and analog results: Geophysics, 62, 6, 1779-1793.

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Article Type: Research Article

Keyword(s): Anisotropy; chargeability; conductivity; hematite; magnetite.

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Abstract

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