Application of Electrical Resistivity Tomography for Cost-Effective Planning in Diabase Gravel Mining Operations in Southeastern Brazil
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Abstract
Planning in mineral extraction is fundamental to the operational and economic success of a mine, with an emphasis on reducing costs during exploration and the safety of operations. This study focused on small-scale mining operations to produce diabase gravel, an important input in civil building. The profile of residential construction in Brazil and other South American countries has historically depended on local materials such as sand, clay and stone. However, the operational viability of small-scale mines is closely linked to low-cost conditions, including soil thickness, rock homogeneity and water pumping costs. This study presents a case of using the geophysical method of electroresistivity, specifically electrical resistivity tomography, in a diabase gravel mining operation. Exploring deeper into the mine, the presence of granite was discovered at different depths, which implies various drilling, blasting and crushing costs. The distinction between diabase and granite, despite their similarities in electrical resistivity, is crucial for mine planning and project viability. The study overcame scientific and technological challenges, based on the geological/structural characteristics of each rock and on climatic and seasonal variables. The use of electrical resistivity tomography proved to be an effective solution, offering satisfactory results for mapping and discriminating between diabase and granite, providing crucial information for mine planning and potentially reducing operating costs. This work highlights the growing importance of applying geophysical methods to small-scale mining operations, as they can be an investigative technique to help with specific challenges faced by these operations.
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References
Aalst, W. V. D. (2016). Process Mining: data science in action. Springer.
ABEM. Terrameter LS (2012) instruction manual. ABEM Instrument, Sundbyberg.
Agência Nacional de Mineração-ANM. (2021) Anuário Mineral Brasileiro, 2021. Ano base 2020. Agência Nacional de Mineração; coordenação técnica de Marina Dalla Costa–Brasília
Aizebeokhai, A. P., Olayinka, A. I., Singh, V. S. & Uhuegbu, C. C. (2011). Effectiveness of 3D geoelectrical resistivity imaging using parallel 2D profiles. Current Sciences, 101(8) 6, 1036–1052.
Binley, A. & Kemna, A. (2005). DC Resistivity and Induced Polarization Methods. In. Rubin, Y., Hubbard.
Camarero, P. L., Moreira, C. A., Targa, D. A., Duz, B. G. & Pereira, H. G. (2022). Analysis of acid drainage flow zones in a rocky massif in a uranium mine from structural and geophysical diagnoses. Mine Water Environ, 41(2), 303-316. Doi: https://doi.org/10.1007/s10230-021-00827-6
Casagrande, M. F. S.; Moreira, C. A. & Targa, D. A. (2020). Study of generation and underground fow of acid mine drainage in waste rock pile in uranium mine using electrical resistivity tomography. Pure Appl Geophysics, 77, 703–721. doi: https://doi.org/10.1007/s00024-019-02351-9
Cortada, U., Martínez, J., Rey, J., Hidalgo, C. & Sandoval, S. (2017). Assessment of tailings pond seals using geophysical and hydrochemical techniques. Engineering Geologyl, 223, 59–70. doi: https://doi.org/10.1016/j.enggeo.2017.04.024
Cortês, A. R. P., Moreira, C. A., Paes, R. A. S. & Veloso, D. I. K. (2019). Geophysical and metalogenetic modelling of the copper occurrence in Camaquã Sedimentary Basin, Brazilian Southern. Pure Appl Geophysics, 176, 4955–4968. doi: https://doi.org/10.1007/s00024-019-02190-8
Dahlin, T. & Zhou, B. (2006). Multiple-gradient array measurements for multichannel 2D resistivity imaging. Near Surface Geophysics, 4(2), 113-123. doi: https://doi.org/10.3997/1873-0604.2005037
Dentith, M. & Mudge, S. T. (2014). Geophysics for the Mineral Exploration Geoscientist. Cambridge University Press, New York.
Druskin, V. (1998). On the uniqueness of inverse problems from incomplete boundary data. Society for Industrial and Aplied Matematics, 58(5), 1591–1693.
Ellis, R. G. & D. W. Oldenburg. (1994). Applied geophysical inversion, Geophysical Journal International, 116(1), 5-11. doi: https://doi.org/10.1111/j.1365-246X.1994.tb02122.x
Frazão, E. B. (2007) Tecnologia para Produção e Utilização de Agregados. In: Agregados para Construção Civil no Brasil: contribuições para formulação de políticas públicas. Belo Horizonte. C ETEC/SGM/MME.
Guireli Netto, L., Singha, K., Moreira, C. A., Gandolfo, O. C. B. & Albarelli, D. S. N. A. (2023). Investigation of fractured rock beneath a uranium-tailing storage dam through UAV digital photogrammetry and seismic refraction tomography. Frontiers in Earth Sciences, 11, 1281076. doi: https://doi.org/10.3389/feart.2023.1281076
Hasui, Y. (2010). A grande colisão pré-cambriana do sudeste brasileiro e a estruturação regional. Geociências, 29(2), 141-169.
Helene, L. P. I., Moreira, C. A. & Bovi, R. (2020). Identification of leachate infiltration and its flow pathway in landfill by means of electrical resistivity tomography (ERT). Environmental Monitoring and Assessment, 192(249). doi: https://doi.org/10.1007/s10661-020-8206-5
Kearey, P., Brooks, M. & Hill, I. (2002). An introduction to geophysical exploration. (3a ed.) United Kingdom: Blackwell Publishing Company.
Lghoul, M., Teixidó, T., Penã, J.A., Hakkou, R., Kchikach, A., Guérin, R., Jaffal, M. & Zouhri, L. (2012). Electrical and seismic tomography used to image the structure of a tailings pond at the abandoned kettara mine, Morocco. Mine Water Environ, 31, 53–61. doi: https://doi.org/10.1007/s10230-012-0172-x
Loke, M. H., & Barker, R. D. (1996). Rapid least-squares inversion of apparent resistivity pseudosections using a quasi-Newton method. Geophysical Prospecting, 44(1), 131–152. doi: https://doi.org/10.1111/j.1365-2478.1996.tb00142.x
Loke, M. H., Acworth, I., & Dahlin, T. (2003). A comparison of smooth and blocky inversion methods in 2D electrical imaging surveys. Exploration Geophysics, 34(3), 182–187. doi: https://doi.org/10.1071/EG03182
Lowrie, W. (2007). Fundamentals of Geophysics. (2a ed.). New York: Cambridge University Press.
Machado, F. B., Rocha Júnior, E. R. V., Marques, L. S. & Nardy, A. J. R. (2015). Volcanological aspects of the northwest region of Paraná continental flood basalts (Brazil). Solid Earth, 6, 227-241. http://hdl.handle.net/11449/129064
Machado, F. B., Rocha Júnior, E. R. V., Marques, L. S., Nardy, A. J. R., Zezzo, L. V. & Marteleto, N. S. (2018). Geochemistry of the Northern Paraná Continental Flood Basalt (PCFB) Province: implications for regional chemostratigraphy. Brazilian Journal of Geology, 48(2), 177-199. doi: https://doi.org/10.1590/2317-4889201820180098
Machado, J. I., Cremonese, D. T. & De Tomi, G. (2020). Development of a low-cost alternative for the monitoring of the ore hauling production indicators in small-scale mining. REM-Internatinal Engineering Journal, 73(3), 379-386. doi: https://doi.org/10.1590/0370-44672019730055
Marques, A. C. G., Moreira, C. A., Casagrande, M. F. S. & Arcila, E. J. A. (2022). Gamma-ray spectrometry applied in the identification of potential acid mine drainage generation zones in waste rock pile with uranium ore and associated sulfides (caldas, Brazil). Geofísica Internacional, 61(3), 251–266. doi: https://doi.org/10.22201/igeof.00167169p.2022.61.3.2207
Menke, W. (2012). Geophysical data analysis: Discrete inverse theory (3a ed.). Academic Press. doi: https://doi.org/10.1016/C2011-0-69765-0
Moon, C. J., Whateley, M. E. G. & Evans, A. M. (2006). Introduction to Mineral Exploration. Blackwell, Malden.
Moreira, C. A., Lapola, M. M. & Carrara, A. (2016). Comparative analyzes among electrical resistivity tomography arrangements in the characterization of flow structure in free aquifer. Geofísica Internacional, 55 (2), 119– 129. doi: https://doi.org/10.22201/igeof.00167169p.2016.55.2.1716
Moreira, C. A., Leandro C. G., Lopes, C. T. & Ilha, L. M. (2017). DC resistivity investigation in a fractured aquifer system contaminated by leachate from an old dump. Geofisica Internacional, 56(4), 345-358. doi: https://doi.org/10.22201/igeof.00167169p.2017.56.4.1827
Moreira, C. A., Netto, L. G., de Siqueira Buchi, F. M. et al. (2024). Using Electrical Resistivity Tomography to Understand the Hydrogeological Behavior of Acid Drainage Percolation in a Fractured Aquifer at a Uranium Mining Site. Mine Water Environ 43, 431–448. doi: https://doi.org/10.1007/s10230- 024-00998-y
Mussett, A. E. & Khan, M. A. (2000). Looking Into The Earth: An Introduction To Geological Geophysics. Nova Iorque: Cambridge University Press.
Nascimento, M. M. P. F., Moreira, C. A., Duz, B. G. & Silveira, A. J. T. (2022). Geophysical diagnosis of diversion channel infiltration in a uranium waste rock pile. Mine Water and the Environment, 41(3), 704-720. doi: https://doi.org/10.1007/s10230-022-00878-3
Oliveira, M., Moreira, C. A., Guireli Netto, L., Nascimento, M. & Sampaio, B. (2022). Geophysical and geological surveys to understand the hydrogeological behavior in an outcrop area of the Guarani Aquifer System, in Brazil. Environmental Challenge, 6, 100448. doi: https://doi.org/10.1016/j.envc.2022.100448
Oliveira, M. A. F., Negri, F. A., Zanardo, A. & Morales, N. (2019). Archean and paleoproterozoic crust generation events, Amparo complex and Serra Negra orthogneiss in southern Brasília Orogen, SE Brazil. Journal of South American Earth Sciences, 90, 137-154. doi: https://doi.org/10.1016/j.jsames.2018.11.029
Oliveira, M. A. F., Zanardo, A., Lazarini, A. P., Silva, A. H. M. & Nardy, A. J. R. (2004). Caracterização petrográfica e geoquímica de rochas anfibolíticas e metamáficas associadas às Faixas Metamórficas Amparo e Itapira na região nordeste de São Paulo. Revista Brasileira de Geociências, 34(3), 393-400. doi: https://doi.org/10.25249/0375-7536.2004343393400
Oyeyemi, K. D., Aizebeokhai, A. P., Metwaly, M., Omobulejo, O., Sanuade, O. A., & Okon, E. E. (2022). Assessing the suitable electrical resistivity arrays for characterization of basement aquifers using numerical modeling. Heliyon, 8(5), doi: https://doi.org/10.1016/j.heliyon.2022.e09427
Reynolds, J. M. (2011). An introduction to applied and environmental geophysics. John Wiley & Sons.
Rocha-Júnior, E. R., Marques, L. S., Babinski, M., Nardy, A. J., Figueiredo, A. M., & Machado, F. B. (2013). Sr–Nd–Pb isotopic constraints on the nature of the mantle sources involved in the genesis of the high-Ti tholeiites from northern Paraná Continental Flood Basalts (Brazil). Journal of South American Earth Sciences, 46, 9-25. doi: https://doi.org/10.1016/j.jsames.2013.04.004
S. S. (Eds) Hydrogeophysics. (pp.12-156)Water Science and Technology Library, Springer. doi: https://doi.org/10.1007/1-4020-3102-5_5
Schneider, R. L., Muhlmann, H., Tommasi, E., Medeiros, R. A., Daemon, R. A. & Nogueira, A. A. (1974). Revisão estratigráfica da Bacia do Paraná. [Sesión de conferencia]. 1947 SBG, 28 Congresso Brasileiro de Geologia, Porto Alegre.
Soares, P. C. (1972). O limite glacial – pós-glacial do Grupo Tubarão no Estado de São Paulo. Anais da Academia Brasileira de Ciências, 44, 333-341.
Targa, D. A., Moreira, C. A. & Casagrande, M. F. S. (2021). Hydrogeological analysis of sulfide tailings at a uranium mine using geophysical and hydrochemical methods. Mine Water and the Environment, 40, 671-689. doi: https://doi.org/10.1007/s10230-021-00791-1
Telford, W. M., Geldart, L. P. & Sheriff, R. E. (1990). Applied geophysics. (2a. ed), New York, Cambrigde University Press.
Tichauer, R., Abreu, G. & De Tomi, G. (2021). Method of Comparable Values: A New Approach for Efficient Exploration Target Selection in Small-Scale Mining. Natural Resources Research. 30, 2029–2046. doi: http://doi.org/10.1007/s11053-021-09855-z
Tichauer, R., Martins, A.C., Silva, R.S. & De Tomi, G. (2020). The role of geophysics in enhancing mine planning decision-making in small-scale mining. Royal Society Open Science, 7(7), 200384. doi: https://doi.org/10.1098 /rsos.200384
Wernick, E. & Penalva, F. (1980). Contribuição a geologia do Grupo Pinhal (SP e MG). Rev Bras Geociênc, 10, 43-62.
Wernick, E. (1972). Granitos porfiros dos arredores de Serra Negra, Valinhos e Amparo e suas relações com o Maciço de Morungaba, Leste do Estado de São Paulo, Rev Bras Geociênc, 2(2), 129-138.
Wernick, E., Artur, A. C., Hôrmann, P.K. & Weber-Diefenbach, K. (1993). Associações Plutônicas do Complexo Granitóide Socorro (Estado de São Paulo e Minas Gerais, SE- Brasil. Rev Bras Geociênc, 23(3), 265-273.
Worlanyo, A. S. & Li, J. (2021). Evaluating the environmental and economic impact of mining for post- mined land restoration and land-use: A review. Journal of Environmental Management, 111623. doi: https://doi.org/10.1016/j.jenvman.2020.111623