Analysis of the potential of acid mine drainage generation from the neutralized coal mining tailings
DOI:
https://doi.org/10.15243/jdmlm.2021.084.2925Keywords:
acid generation, coal mining, contamination, groundwater, XRF and XRDAbstract
Mining activities specifically Coal Mining have been long testified to be one of the major contributing factors to environmental crisis, with Acid Mine Drainage (AMD) as one of the leading indicators. The purpose of this study was to assess the potential of AMD generation from neutralized coal mining tailings. In order to achieve the ultimate objective of the study, analysis of chemical composition and mineral content of the tailings using XRF (X-Ray Fluorescence) and XRD (X-Ray Diffraction) respectively, lastly, a static analysis such as ABA (Acid Base Accounting) and TCLP (Toxic Characteristic Leaching Procedure) were also conducted. The results have shown that the studied tailing samples had relatively higher Acid Potential (19 kg CaCO3/t to 20 kg CaCO3/t) versus the Neutralizing Potential (NP) (14 kg CaCO3/t to 18 kg CaCO3/t). It was also found that the Net Neutralizing Potential Ratio (NNPR) is less than zero (-1.5 kg CaCO3/t to -5.40 kg CaCO3/t which indicates that the tailings have the potential to generate acid. The low concentration of CaO indicates acidic potential of the samples because CaO is a buffering mineral. Based on the results of the study, it was concluded that Mine Tailings has the potential to generate acid; therefore, the contamination to the nearby watercourses is extremely possible if necessary remedial actions should be considered.References
Akcil, A. and Koldas, K. 2006. Acid Mine Drainage (AMD: causes, treatment and case studies. Journal of Cleaner Production 14: 1139-1146.
Alpers, C.N., Blowes, D.W., Nordstrom, D.K. and Jambor, J.L 1994. Secondary Minerals and acid mine water chemistry. In: Jambor J.L, Blowes D.W (eds), The Environmental geochemistry of sulphide mine water: Mineralogical Association of Canada, Short Course Handbook, vol.22, pp 247-270.
Aucamp, P. and Van Schalkwyk, A. 2003. Trace element pollution of soils by abandoned gold mine tailings near Potchefstroom, South Africa. Department of Geology, University of Pretoria, South Africa.
Department of Environmental Affairs (DEA) (2013). National norms and standards for remediation and contaminated land and soil quality in the Republic of South Africa.
Hlavay, J., Prohaska, T., Weisz, M., Wenzel, W.W. and Stingender, G.T. 2004. Determination of trace element bound to soils and sediment fractions. IUPAC Technical Report. Pure and Applied Chemistry 76: 415-442.
Hodgson, F.D.I. and Kranz, R.M. 1998. Investigation into groundwater quality deterioration in the Olifants catchment above the Loskop dam with specialised investigation in the Witbank dam sub-catchment. WRC Report 291/1/98 Pretoria: Water Research Commission.
Jambor, J.L 1994. Mineralogy of sulphide-rich tailings and their oxidation products In: Jambor J.L, Blowes D.W (Eds, The Environmental geochemistry of sulphide mine water: Mineralogical Association of Canada, Short Course Handbook, v.22, pp 103-132.
Jambor, J.L 2003. Mine-waste mineralogy and Mineralogical perspectives of Acid Base Accounting. In J.L Jambor, D.W Blowes, A.I.M Ritchie (Eds), Environmental Aspects of Mine Waters, Short Course Series, Mineralogical Association of Canada, vol 31, pp 117-146.
Kabata-Pendias, A. 1994. Agricultural problems related to excessive trace elements content of soils. In: Salomons, W., Mader, P. and Forstner, U. (eds): Pathways, impacts and engineering aspects of metal polluted sites. Berlin: Springer.
Kwong, Y.T.J. 1993. Prediction and prevention of Acid Rock Drainage from geological and Mineralogical perspective, MEND Report1.32.1 Ottawa, ON (NHRI Contribution CS-92054).
Lapakko, K.A. 1993. Predictive Testing for Mine Waste Drainage Quality. In Mine Operation and Closure Short Course. Sponsored by EPA and others April 27 - 29, 1993. Helena, MT.
Rosner, T. 1999. The environmental impact of seepage from gold mine tailings dams near Johannesburg, South Africa. Department of Geology, University of Pretoria, South Africa.
Sobek, A.A., Schuller, W.A., Freeman, J.R. and Smith, R.M. 1978. Field and laboratory methods applicable to overburdens and mine soils. EPA-600/2-78-054. USEPA. Cincinnati. Ohio.
Soregaroli, B.A. and Lawrence, R.W. 1998. Update on waste Characterisation Studies. Proceeding of Mine Design, Operations and Closure Conference. Polson, Montana.
U.S. Environmental Protection Agency, Office of Research and Development. 1992. Draft. Predicting Acid Generation From Non-Coal Mining Waste: Notes of July 1992 Workshop. Prepared for the Environmental Monitoring Systems Laboratory, Las Vegas, NV 89193-3478 by SAIC, Falls Church, VA.
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