Abstract
Acid mine drainage is an important environmental hazard due to its serious chemical contamination to the surface and groundwater resources. To provide enough and representative data for developing restoration techniques, this time-dependent geochemical process should be investigated based on kinetic principles. Thus, the kinetic column test generally utilized in the earlier studies without any accepted procedures related to the column dimension and properties of materials such as particle size and mass of samples to be tested for this purpose. To overcome the dissimilarities between the mass release rate of contaminants specified in the laboratory and in the field, and to upscale laboratory-based measurements to the field, kinetic column tests were performed by using different columns filled with crushed coarse and fine ore samples. The fluctuations of pH values and the concentration of various constituents were determined during kinetic column tests. The effluents of columns turned to acid after a lag time of between 21 and 65 weeks depending on the column dimensions and particle size. Statistically significant predictive models for upscaling geochemical behaviour of AMD processes were presented based on simple and multiple regression analyses among column dimensions and main parameters controlling the rate of acid generation.
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References
Andrina J, Wilson GW, Miller S, Neale A (2006) Performance of the acid rock drainage mitigation waste rock trial dump at Grasberg mine. In: 7th International Conference on Acid Rock Drainage (ICARD), St. Louis, United States, pp. 30–44
Benzaazoua M, Bussière B, Dagenais A-M, Archambault M (2004) Kinetic tests comparison and interpretation for prediction of the Joutel tailings acid generation potential. Environ Geol 46:1086–1101
Bradham WS, Caruccio FT (1990) A comparative study of tailings analysis using acid/base accounting, cells, columns and Soxhelets. Proceeding of the 1990 Mining and Reclamation Conference and Exhibition, Charleston, WV, 19-25
Bradham WS, Caruccio FT (1991) A comparative study of tailings analysis using acid/base accounting, cells, columns and Soxhlets. In: 2nd Int Conf Abatement of Acidic Drainage, Montre´al, Vol. 1. CANMET, Ottawa, Canada, 157–173
Cruz R, Bertrand V, Monroy M, Gonzalez I (2001) Effect of sulfide impurities on the reactivity of pyrite and pyritic concentrates: a multi-tool approach. Appl Geochem 16(7-8):803–819
Demers I, Bussiére B, Benzaazoua M, Mbonimpa M, Blier A (2008) Column test investigation on the performance of monolayer covers made of desulphurized tailings to prevent acid mine drainage. Miner Eng 21:317–329
EMCBC (1996) The perpetual pollution machine. Acid mine drainage, BC Mining Control, Canada
EPA (2003) U.S. Environmental Protection Agency, “Developing water quality criteria for suspended and bedded sediments (SABS): potential approaches”. A U.S. EPA Science Advisory Board Consultation
Feasby DG, Tremblay GA (1995) New technologies to reduce environmental liability from acid generating mine waste. In: Hyne TP, Blanchette MV (eds) Proc of Subury 95 Mining and the Environ, Ontario, vol 2, pp 643–647
García C, Ballester A, González F, Blázquez ML (2005) Pyrite behaviour in a tailings pond. Hydrometallurgy 76:25–36
González-Sandoval MR, Menidola LL, Sánchez-Tovar SA, Durán-Domínguez MC (2009) Humidity cell tests: effect of air flow and cycle duration in the quality of leachates. In: Securing the Future and 8th ICARD: Proceedings of the Conference, Skellefteå, Sweden, pp. 331–340
Grande JA, Beltran R, Sainz A, Santos JC, de la Torre ML, Borrego J (2005) Acid mine drainage and acid rock drainage processes in the environment of Herrerías Mine (Iberian Pyrite Belt, Huelva-Spain) and impact on the Andevalo Dam. Environ Geol 47(2):185–196
Herrera P, Uchiyama H, Igarashi T, Asakura K, Ochi Y, Iyatomi N, Nagae S (2007) Treatment of acid mine drainage through a ferrite formation process in central Hokkaido, Japan: evaluation of dissolved silica and aluminium interference in ferrite formation. Miner Eng 20(13):1255–1260
Hood W, Oertel A (1984) A leaching column method for predicting effluent quality from surface mines. In Proc. Symp. on Surface Mining Hydrology, Sedimentology and Reclamation, University of Kentucky
Hornberger RJ, Brady KBC (1998) Kinetic (leaching) tests for the prediction of mine drainage quality (chapter 7); coal mine drainage prediction and pollution prevention in Pennsylvania, K.B.C Brady, M.W., Smith and J. Schueck (eds), The report of the Pennsylvania Department of Environmental Protection, Harrisburg, 5600-BK-DEP2256, PA DEP, 7-1 to 7.54
ISRM (2007) The Complete ISRM Suggested Methods for Rock Characterization, Testing and Monitoring: 1974-2006. In: Ulusay R, Hudson JA (eds) Suggested Methods Prepared by the Commission on Testing Methods. International Society for Rock Mechanics (ISRM), Ankara
Kalyoncu Erguler G, Erguler ZA, Akcakoca H, Ucar A (2014) The effect of column dimensions and particle size on the results of kinetic column test used for acid mine drainage (AMD) prediction. Miner Eng 55:18–29
Lapakko KA, Engstrom JN, Antonson DA (2006) Effects of particle size on drainage quality from three lithologies. In: 7th International Conference on Acid Rock Drainage (ICARD), St. Louis, United States, pp. 1026–1030
Lawrence RW, Marchant PB (1991) Acid Rock Drainage Prediction Manual. Report CANMET, MEND Project 1.16.1b, Canada
Lewis J, Sjöstrom J (2010) Optimizing the experimental design of soil columns in saturated and unsaturated transport experiments. J Contam Hydrol 115(1-4):1–13
Morin KA, Hutt NM (1997) Environmental geochemistry of mine site drainage: practical theory and case studies. MDAG Publishing, Vancouver, Canada
Murr LE, Cathles LM, Reese DH, Hiskey JB, Popp CJ, Brierly JA, Boss D, Berry VK, Schlitt WJ, Hsu PC (1977) Chemical, biological and metallurgical aspects of large scale column leaching experiments for solution mining and in situ leaching. In Situ 1(3):209–233
Naka A, Yasutaka T, Sakanakura H, Kalbe U, Watanabe Y, Inoba S, Takeo M, Inui T, Katsumi T, Fujikawa T, Sato K (2016) Column percolation test for contaminated soils: key factors for standardization. J Hazard Mater 320:326–340
Parbhakar-Fox A, Lottermoser BG (2015) A critical review of acid rock drainage prediction methods and practices. Miner Eng 82:107–124
Parbhakar-Fox AK, Edraki M, Walters S, Bradshaw D (2011) Development of a textural index for the prediction of acid rock drainage. Miner Eng 24(12):1277–1287
Parbhakar-Fox A, Lottermoser B, Bradshaw D (2013) Evaluating waste rock mineralogy and microtexture during kinetic testing for improved acid rock drainage prediction. Miner Eng 52:111–124
Park I, Tabelin CB, Jeon S, Li X, Seno K, Ito M, Hiroyoshi N (2019) A review of recent strategies for acid mine drainage prevention and mine tailings recycling. Chemosphere 219:588–606
Robertson A. Mac G, Broughton LM (1992) Reliability of acid rock drainage testing, Workshop on U.S. EPA Specifications for Tests to Predict Acid Generation from Non-Coal Mining Wastes, Las Vegas, Nevada, July 30-31.
Sapsford DJ, Bowell RJ, Dey M, Williams KP (2009) Humidity cell tests for the prediction of acid rock drainage. Miner Eng 22(1):25–36
Scharer JM, Garga V, Smith R, Halbert BE (1991) Use of steady state models for assessing acid generation in pyritic mine tailings. In Proceedings Second International Conference on the Abatement of Acidic Drainage, September 16-18, 1991, Montreal, Canada, Volume 2, 211-230
Smart R, Skinner WM, Levay G, Gerson AR, Thomas JE, Sobieraj H, Schumann R, Weisener CG, Weber PA, Miller SD, Stewart WA (2002) ARD test handbook: Project P387, A prediction and kinetic control of acid mine drainage. AMIRA, International Ltd, Melbourne 42 pp
Smith LJ, Neuner M, Gupton M, Moore M, Bailey BL, Blowes DW, Smith L, Sego DC (2009) Diavik waste rock project: from the laboratory to the Canadian arctic. In: Securing the Future and 8th ICARD: Proceedings of the Conference, Skellefteå, Sweden, pp. 40–50.
Strömberg B, Banwart S (1999) Weathering kinetics of waste rock from the Aitik copper mine, Sweden: scale dependent rate factors and pH controls in large column experiments. J Contam Hydrol 39:59–89
Tabelin CB, Sasaki R, Igarashi T, Park I, Tamoto S, Arima T, Ito M, Hiroyoshi N (2017a) Simultaneous leaching of arsenite, arsenate, selenite, and selenate, and their migration in tunnel-excavated sedimentary rocks: I. Column experiments under intermittent and unsaturated flow. Chemosphere 186:558–569
Tabelin CB, Sasaki R, Igarashi T, Park I, Tamoto S, Arima T, Ito M, Hiroyoshi N (2017b) Simultaneous leaching of arsenite, arsenate, selenite, and selenate, and their migration in tunnel-excavated sedimentary rocks: II. Kinetic and reactive transport modeling. Chemosphere 188:444–454
Tabelin CB, Veerawattananun S, Ito M, Hiroyoshi N, Igarashi T (2017c) Pyrite oxidation in the presence of hematite and alumina: I. Batch leaching experiments and kinetic modeling calculations. Sci Total Environ 580:687–689
Tabelin CB, Igarashi T, Villacorte-Tabelin M, Park I, Opiso EM, Ito M, Hiroyoshi N (2018) Arsenic, selenium, boron, lead, cadmium, copper, and zinc in naturally contaminated rocks: a review of their sources, modes of enrichment, mechanisms of release, and mitigation strategies. Sci Total Environ 645:1522–1553
Tamoto S, Tabelin CB, Igarashi T, Ito M, Hiroyoshi N (2015) Short and long term release mechanisms of arsenic, selenium and boron from tunnel-excavated sedimentary rock under in situ conditions. J Contam Hydrol 175-176:60–71
Tatsuhara T, Arima T, Igarashi T, Tabelin CB (2012) Combined neutralization-adsorption system for the disposal of hydrothermally altered excavated rock producing acidic leachate with hazardous elements. Eng Geol 139:76–84
USBR (United States Bureau of Reclamation) (1974) Earth Manuak. US Department of Interior Bureau of Reclamation. A Water Resources Technical Publication, 810 p
Weatherell CJ, Feasby DG, Tremblay GA (1997) The mine environment natural drainage program. In: Proc of PMI 97, 28th Annual Seminars and Symp, Chicago
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The authors gratefully acknowledge the financial support of the General Directorate of Mineral Research and Exploration (MTA) (MTA Project no: 2012-37-14-01-9).
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Responsible Editor: Amjad Kallel
This paper was selected from the 1st Conference of the Arabian Journal of Geosciences (CAJG), Tunisia 2018
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Kalyoncu Erguler, G., Erguler, Z.A. The evaluation of acid mine drainage by kinetic procedures and empirical models for field scale behaviour. Arab J Geosci 13, 387 (2020). https://doi.org/10.1007/s12517-020-05372-0
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DOI: https://doi.org/10.1007/s12517-020-05372-0