Multi‐geophysical methods for characterizing fractures in an open pit mine, western Bushveld Complex, South Africa
In the Bushveld Complex, South Africa, open pit mines are faced with a challenge of rock slope stability due to geological structures (fractures, faults and dykes) that compartmentalize the rock mass. Geophysical surveys (seismics, magnetics and electrical methods) were conducted in a 0.2 km2 area a...
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| Veröffentlicht in: | Geophysical Prospecting 2024-06, Vol.72 (5), p.1950-1970 |
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| container_title | Geophysical Prospecting |
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| creator | Rapetsoa, Moyagabo K. Gomo, Sikelela Manzi, Musa S. D. James, Ian Dildar, Jureya Sihoyiya, Mpofana Mutshafa, Ndamulelo Durrheim, Raymond J. |
| description | In the Bushveld Complex, South Africa, open pit mines are faced with a challenge of rock slope stability due to geological structures (fractures, faults and dykes) that compartmentalize the rock mass. Geophysical surveys (seismics, magnetics and electrical methods) were conducted in a 0.2 km2 area at Tharisa mine, with the goal to delineate fractures that may be potential conduits for water migration into the pit. Special processing techniques were applied to the dataset to obtain good quality seismic, magnetic and resistivity models. The P‐wave velocity models show distinct low velocities in the centre of the seismic profile, indicating the presence of weak zones associated with faulting or fracturing. Seismic reflection method was used to image the deeper discontinuities and mineralization contacts. Near surface reflections are observed throughout the profiles and are correlated with the contact between the chromitite and host rock. Ground magnetic surveys were conducted to delineate dykes and fractures. De‐trending and de‐culturing techniques were applied on the magnetic data for correcting regional and temporal variations. The low magnetic regions indicate the presence of fracture systems in the subsurface, whereas the high magnetic region is correlated with the dolerite dyke that crosscuts the pit. The electrical resistivity tomography exhibits linear low resistivity contrast zones that differentiate between the fractured and undisturbed hard rock at an estimated depth of 4–10 m. Resistivity shows discontinuities that suggests the presence of fracturing and dyke‐host rock contacts. Correlation among magnetics, P‐wave velocity models, resistivity section and seismic data is evident when overlaying the different datasets, implying that the low magnetic regions are highly weathered and prone to fracturing. The integration of geophysical data is encouraging, because it was able to image the depth to the bedrock, fractures within the host rock and dyke in a complex mining environment. |
| doi_str_mv | 10.1111/1365-2478.13489 |
| format | Article |
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D. ; James, Ian ; Dildar, Jureya ; Sihoyiya, Mpofana ; Mutshafa, Ndamulelo ; Durrheim, Raymond J.</creator><creatorcontrib>Rapetsoa, Moyagabo K. ; Gomo, Sikelela ; Manzi, Musa S. D. ; James, Ian ; Dildar, Jureya ; Sihoyiya, Mpofana ; Mutshafa, Ndamulelo ; Durrheim, Raymond J.</creatorcontrib><description>In the Bushveld Complex, South Africa, open pit mines are faced with a challenge of rock slope stability due to geological structures (fractures, faults and dykes) that compartmentalize the rock mass. Geophysical surveys (seismics, magnetics and electrical methods) were conducted in a 0.2 km2 area at Tharisa mine, with the goal to delineate fractures that may be potential conduits for water migration into the pit. Special processing techniques were applied to the dataset to obtain good quality seismic, magnetic and resistivity models. The P‐wave velocity models show distinct low velocities in the centre of the seismic profile, indicating the presence of weak zones associated with faulting or fracturing. Seismic reflection method was used to image the deeper discontinuities and mineralization contacts. Near surface reflections are observed throughout the profiles and are correlated with the contact between the chromitite and host rock. Ground magnetic surveys were conducted to delineate dykes and fractures. De‐trending and de‐culturing techniques were applied on the magnetic data for correcting regional and temporal variations. The low magnetic regions indicate the presence of fracture systems in the subsurface, whereas the high magnetic region is correlated with the dolerite dyke that crosscuts the pit. The electrical resistivity tomography exhibits linear low resistivity contrast zones that differentiate between the fractured and undisturbed hard rock at an estimated depth of 4–10 m. Resistivity shows discontinuities that suggests the presence of fracturing and dyke‐host rock contacts. Correlation among magnetics, P‐wave velocity models, resistivity section and seismic data is evident when overlaying the different datasets, implying that the low magnetic regions are highly weathered and prone to fracturing. The integration of geophysical data is encouraging, because it was able to image the depth to the bedrock, fractures within the host rock and dyke in a complex mining environment.</description><identifier>ISSN: 0016-8025</identifier><identifier>EISSN: 1365-2478</identifier><identifier>DOI: 10.1111/1365-2478.13489</identifier><language>eng</language><publisher>Houten: Wiley Subscription Services, Inc</publisher><subject>Correlation ; Culture techniques ; Datasets ; Discontinuity ; Electric contacts ; Electrical raceways ; Electrical resistivity ; Fractures ; Fracturing ; Geological faults ; Geological structures ; Geophysical data ; Geophysical exploration ; Geophysical methods ; Geophysical surveys ; groundwater ; hydromigration ; imaging ; interpretation ; Magnetic data ; Magnetic surveys ; Mineralization ; Open pit mining ; Rock ; Rock masses ; Rocks ; Seismic analysis ; Seismic data ; Seismic profiles ; Seismic reflection profiling ; Seismic stability ; Seismic surveys ; Seismic velocities ; Slope stability ; Temporal variations ; Tomography ; Wave velocity</subject><ispartof>Geophysical Prospecting, 2024-06, Vol.72 (5), p.1950-1970</ispartof><rights>2024 The Authors. published by John Wiley & Sons Ltd on behalf of European Association of Geoscientists & Engineers.</rights><rights>2024. 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The P‐wave velocity models show distinct low velocities in the centre of the seismic profile, indicating the presence of weak zones associated with faulting or fracturing. Seismic reflection method was used to image the deeper discontinuities and mineralization contacts. Near surface reflections are observed throughout the profiles and are correlated with the contact between the chromitite and host rock. Ground magnetic surveys were conducted to delineate dykes and fractures. De‐trending and de‐culturing techniques were applied on the magnetic data for correcting regional and temporal variations. The low magnetic regions indicate the presence of fracture systems in the subsurface, whereas the high magnetic region is correlated with the dolerite dyke that crosscuts the pit. The electrical resistivity tomography exhibits linear low resistivity contrast zones that differentiate between the fractured and undisturbed hard rock at an estimated depth of 4–10 m. Resistivity shows discontinuities that suggests the presence of fracturing and dyke‐host rock contacts. Correlation among magnetics, P‐wave velocity models, resistivity section and seismic data is evident when overlaying the different datasets, implying that the low magnetic regions are highly weathered and prone to fracturing. The integration of geophysical data is encouraging, because it was able to image the depth to the bedrock, fractures within the host rock and dyke in a complex mining environment.</description><subject>Correlation</subject><subject>Culture techniques</subject><subject>Datasets</subject><subject>Discontinuity</subject><subject>Electric contacts</subject><subject>Electrical raceways</subject><subject>Electrical resistivity</subject><subject>Fractures</subject><subject>Fracturing</subject><subject>Geological faults</subject><subject>Geological structures</subject><subject>Geophysical data</subject><subject>Geophysical exploration</subject><subject>Geophysical methods</subject><subject>Geophysical surveys</subject><subject>groundwater</subject><subject>hydromigration</subject><subject>imaging</subject><subject>interpretation</subject><subject>Magnetic data</subject><subject>Magnetic surveys</subject><subject>Mineralization</subject><subject>Open pit mining</subject><subject>Rock</subject><subject>Rock masses</subject><subject>Rocks</subject><subject>Seismic analysis</subject><subject>Seismic data</subject><subject>Seismic profiles</subject><subject>Seismic reflection profiling</subject><subject>Seismic stability</subject><subject>Seismic surveys</subject><subject>Seismic velocities</subject><subject>Slope stability</subject><subject>Temporal variations</subject><subject>Tomography</subject><subject>Wave velocity</subject><issn>0016-8025</issn><issn>1365-2478</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2024</creationdate><recordtype>article</recordtype><sourceid>24P</sourceid><recordid>eNqFkMtOwzAQRS0EEqWwZmuJLWntOM5jWSooSEUgHmsr8aNxlcTBTihlxSfwjXwJDkVs8Wbk0b1zZw4ApxhNsH9TTGIahFGSTjCJ0mwPjP46-2CEEI6DFIX0EBw5t0aIIEqjEehu-6rTXx-fK2nacus0zytYy640wkFlLORlbnPeSavfdbOCavj0VjqoG5g30LSyga3uYK0beQ430nlpAy96V77KSsC5qdtKvp3DR9N3JZwp6xOOwYHKKydPfusYPF9dPs2vg-Xd4mY-WwacYJQFaahUGPMi4xnhIS7ysFBRHsVJiqkoCk6yWOAkTQQVqZAExxRFSuIYo6IQKKJkDM52c1trXnq_Glub3jY-kvnzk9CHxNirpjsVt8Y5KxVrra5zu2UYsQEtG0CyAST7QesddOfY6Epu_5Ozxf3DzvcNmcB9Jw</recordid><startdate>202406</startdate><enddate>202406</enddate><creator>Rapetsoa, Moyagabo K.</creator><creator>Gomo, Sikelela</creator><creator>Manzi, Musa S. 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D.</au><au>James, Ian</au><au>Dildar, Jureya</au><au>Sihoyiya, Mpofana</au><au>Mutshafa, Ndamulelo</au><au>Durrheim, Raymond J.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Multi‐geophysical methods for characterizing fractures in an open pit mine, western Bushveld Complex, South Africa</atitle><jtitle>Geophysical Prospecting</jtitle><date>2024-06</date><risdate>2024</risdate><volume>72</volume><issue>5</issue><spage>1950</spage><epage>1970</epage><pages>1950-1970</pages><issn>0016-8025</issn><eissn>1365-2478</eissn><abstract>In the Bushveld Complex, South Africa, open pit mines are faced with a challenge of rock slope stability due to geological structures (fractures, faults and dykes) that compartmentalize the rock mass. Geophysical surveys (seismics, magnetics and electrical methods) were conducted in a 0.2 km2 area at Tharisa mine, with the goal to delineate fractures that may be potential conduits for water migration into the pit. Special processing techniques were applied to the dataset to obtain good quality seismic, magnetic and resistivity models. The P‐wave velocity models show distinct low velocities in the centre of the seismic profile, indicating the presence of weak zones associated with faulting or fracturing. Seismic reflection method was used to image the deeper discontinuities and mineralization contacts. Near surface reflections are observed throughout the profiles and are correlated with the contact between the chromitite and host rock. Ground magnetic surveys were conducted to delineate dykes and fractures. De‐trending and de‐culturing techniques were applied on the magnetic data for correcting regional and temporal variations. The low magnetic regions indicate the presence of fracture systems in the subsurface, whereas the high magnetic region is correlated with the dolerite dyke that crosscuts the pit. The electrical resistivity tomography exhibits linear low resistivity contrast zones that differentiate between the fractured and undisturbed hard rock at an estimated depth of 4–10 m. Resistivity shows discontinuities that suggests the presence of fracturing and dyke‐host rock contacts. Correlation among magnetics, P‐wave velocity models, resistivity section and seismic data is evident when overlaying the different datasets, implying that the low magnetic regions are highly weathered and prone to fracturing. The integration of geophysical data is encouraging, because it was able to image the depth to the bedrock, fractures within the host rock and dyke in a complex mining environment.</abstract><cop>Houten</cop><pub>Wiley Subscription Services, Inc</pub><doi>10.1111/1365-2478.13489</doi><tpages>21</tpages><orcidid>https://orcid.org/0000-0002-1655-3529</orcidid><orcidid>https://orcid.org/0000-0003-3275-8994</orcidid><orcidid>https://orcid.org/0000-0003-1956-5223</orcidid><orcidid>https://orcid.org/0000-0002-1654-5211</orcidid><oa>free_for_read</oa></addata></record> |
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| subjects | Correlation Culture techniques Datasets Discontinuity Electric contacts Electrical raceways Electrical resistivity Fractures Fracturing Geological faults Geological structures Geophysical data Geophysical exploration Geophysical methods Geophysical surveys groundwater hydromigration imaging interpretation Magnetic data Magnetic surveys Mineralization Open pit mining Rock Rock masses Rocks Seismic analysis Seismic data Seismic profiles Seismic reflection profiling Seismic stability Seismic surveys Seismic velocities Slope stability Temporal variations Tomography Wave velocity |
| title | Multi‐geophysical methods for characterizing fractures in an open pit mine, western Bushveld Complex, South Africa |
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