Integration of ground geophysical methods to characterize near‐surface aquifer zones within an active mine

Understanding near‐surface groundwater storage, flow patterns, surface and groundwater interactions in mining areas can assist in making mining more efficient and profitable. This is especially important in opencast mines affected by water inflows that may negatively affect production and increase m...

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Veröffentlicht in:Near surface geophysics (Online) 2024-10, Vol.22 (5), p.521-538
Hauptverfasser: Gomo, Sikelela, Mutshafa, Ndamulelo, Dildar, Jureya, Manzi, Musa S. D., Bourdeau, Julie E., Brodic, Bojan, James, Ian, Cooper, Gordon R. J., Durrheim, Raymond J.
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Sprache:eng
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Zusammenfassung:Understanding near‐surface groundwater storage, flow patterns, surface and groundwater interactions in mining areas can assist in making mining more efficient and profitable. This is especially important in opencast mines affected by water inflows that may negatively affect production and increase mining costs. We map and characterize the near‐surface aquifer zones at the opencast site of Tharisa Minerals, located in the southwestern region of the Bushveld Complex (South Africa). The main goal is to infer pit water inflow at the mine site and determine how it may be better controlled. The Bushveld Complex hosts partially connected and unconfined alluvial, shallow‐weathered and crystalline bedrock aquifers, which are often connected by small‐scale permeable zones. Seismic refraction tomography, multichannel analysis of surface waves, electrical resistivity tomography and borehole data are used to map and understand the different aquifer zones in the vicinity of the mine, as well as infer their relation to water inflow in the mine pits. The geophysical surveys map the overburden, weathered bedrock aquifer zone, and the top of the crystalline aquifer rock zone reasonably well. They reveal extensive and deep weathering, and possible high hydraulic conductivity in the vicinity of the mine. The results provide a better understanding of the mine's near‐surface environment, which could be used to implement effective and targeted dewatering techniques, thus enabling better pit inflow water control to improve mine working conditions and production.
ISSN:1569-4445
1873-0604
DOI:10.1002/nsg.12314