Smart solution to a sticky problem: in-mine clay mapping using high-resolution geophysics

G. F. Burnham; P. J. Hawke

doi:10.1071/ASEG2003ab067

ISSN: 2202-0586
E-ISSN:

oa Smart solution to a sticky problem: in-mine clay mapping using high-resolution geophysics
Authors G. F. Burnham^a and P. J. Hawke^b
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^a Mesa J Mine, Robe River Iron Associates,, [email protected] ^b The University of Western Austalia,, [email protected]
Publisher: Australian Society of Exploration Geophysicists
Source: ASEG Extended Abstracts, Volume 2003, Issue ASEG2003 - 16th Geophysical Conference, Aug 2003, p. 1 - 7
DOI: https://doi.org/10.1071/ASEG2003ab067
- Published online: 01 Aug 2003

Abstract

Within the Mesa J pisolite iron ore mine, clay is distributed unevenly and often forms pods and channels less than 10 m in width. The mine resource model, based on 50 m x 50 m spaced drilling, has been unable to accurately delineate the clay for scheduling and mining purposes. Therefore, alternative methods for mapping the clay-contaminated ore were sought.

Predictive clay mapping will significantly reduce production costs at Mesa J through improved selective mining practices, more accurate scheduling, reduced wear on mining equipment and minimising the need for maintenance of haul roads and ramps.

High lateral resolution electromagnetic (EM) surveying using the Geonics EM31 tool can quickly delineate the extent and orientation of the clays. A block model based on the interpretation of the EM data accurately predicts the volume and tonnage of ore and waste material. While rip-line mapping, infill drilling, ground penetrating radar and gravity can delineate clay to varying degrees of success, none were as efficient as EM31.

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2003-08-01

2026-01-18

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References

Morris, R C, Ramanaidou, E R, and Horwitz, R C. 1993. Channel Iron Deposits of the Hamersley Province, CSIRO/AMIRA Iron Ores of the Hamersley Province Project P75G, Exploration and Mining Restricted Report 399R.
Williams, I R. 1968, Yarmlula, WA - 1:250 000, geological series, Geological Survey of Western Australia.

/content/journals/10.1071/ASEG2003ab067

Article Type: Research Article

Keyword(s): electromagnetic; gravity; ground penetrating radar; iron pisolite; mine geophysics

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Abstract

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