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Identification of Flow Zones Inside and at the Base of a Uranium Mine Tailings Dam Using Geophysics
Potential problems related to a tailings dam’s stability are a matter of concern, especially where structural failure might endanger nearby communities and the environment. The Osamu Utsumi mine, located in the State of Minas Gerais, is currently not operating. The rock-soil tailings dam has water u...
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| Published in: | Mine water and the environment 2021-03, Vol.40 (1), p.308-319 |
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| container_title | Mine water and the environment |
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| creator | Arcila, Erika Juliana Aldana Moreira, César Augusto Camarero, Pedro Lemos Casagrande, Matheus Felipe Stanfoca |
| description | Potential problems related to a tailings dam’s stability are a matter of concern, especially where structural failure might endanger nearby communities and the environment. The Osamu Utsumi mine, located in the State of Minas Gerais, is currently not operating. The rock-soil tailings dam has water upwelling downstream in the bedrock, with water flux confined to rock fractures. This research was conducted to identify possible flux zones in the base of the dam using DC resistivity and electrical resistivity tomography (ERT). The data acquisition consisted of five ERT lines with 6 m of spacing between electrodes, using a Schlumberger array. The results are presented by 2D and 3D geophysical models comprising measured and processed resistivity values. It was possible to identify a low resistivity zone (5–20 Ωm), whose structural continuity indicates water infiltration in the bedrock under the dam. Moreover, the results do not indicate that erosion is taking place in the interior of the dam, reducing the risk of geotechnical instability and failure of physical integrity. |
| doi_str_mv | 10.1007/s10230-020-00746-y |
| format | article |
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The Osamu Utsumi mine, located in the State of Minas Gerais, is currently not operating. The rock-soil tailings dam has water upwelling downstream in the bedrock, with water flux confined to rock fractures. This research was conducted to identify possible flux zones in the base of the dam using DC resistivity and electrical resistivity tomography (ERT). The data acquisition consisted of five ERT lines with 6 m of spacing between electrodes, using a Schlumberger array. The results are presented by 2D and 3D geophysical models comprising measured and processed resistivity values. It was possible to identify a low resistivity zone (5–20 Ωm), whose structural continuity indicates water infiltration in the bedrock under the dam. 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| ispartof | Mine water and the environment, 2021-03, Vol.40 (1), p.308-319 |
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| source | Springer Nature |
| subjects | Bedrock Case studies Clay Dam stability Dams Data acquisition Earth and Environmental Science Earth Sciences Ecotoxicology Electrical resistivity Fractures Geology Geophysics Hydrogeology Industrial Pollution Prevention Lithology Mine tailings Mine wastes Mineral Resources Mining Ocean circulation Risk reduction Rocks Soil erosion Soil water Structural failure Tailings Technical Article Three dimensional models Tomography Topography Upwelling Uranium Water infiltration Water Quality/Water Pollution |
| title | Identification of Flow Zones Inside and at the Base of a Uranium Mine Tailings Dam Using Geophysics |
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