Abstract
This study assessed arsenic (As) contamination and the characteristics of secondary minerals in mine drainage using integrated acid–base accounting (ABA) and toxicity characterisation leaching procedure (TCLP), aqueous and solid-phase media monitoring, as well as a textural and mineralogical analysis of tailings material at the Obuasi mine in Ghana. The neutralisation potential and maximum potential acidity from an ABA test; As and pH in TCLP leachate and mine drainage, particle size, trace and major elements in tailings, were analyzed using the relevant methodologies. The ABA results which indicated a high tendency for acid generation were interpreted using a four data point model developed for the purpose. The model allows an additional 40 kg CaCO3/ton amendment value to take care of any delayed acidification. Arsenic leaching simulations are described by the equation: [As] \(= {\text{A }}\left( {\frac{\text{NP}}{\text{MPA}}} \right)^{2} - \;{\text{B}}\left( {\frac{\text{NP}}{\text{MPA}}} \right)\; + \;{\text{C}}\). With the y-axis set to zero, pH simulation equations are defined by pH = K\(\left( {\frac{\text{NP}}{\text{MPA}}} \right)\), where the K and pH values ranging from 82 to 100 and 4.1 to 9.0 respectively, represent limits within which natural attenuation of As in drainage can be sustained. Expressing the pH equation above in the form, pH = (ln |R2| − lnK), the simulation equations defined the range 2.2–4.6 which conformed to pH range for which secondary minerals such as jarosite, schwertmannite and ferrihydrite, could occur as buffering agents in mine drainage. Also, molar value plot for Fe2O3 against Al2O3 indicate the precipitation of goethite and alunite into tailings, while increased fines and As enrichment in older tailings confirmed As attenuation. Such information is relevant for front-end planning for As impact remediation in mine drainage.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Appelo CAJ, Postma D (2005) Geochemistry, ground-water, and pollution, 2nd edn. Balkema, Netherlands 536 pp
BC AMD Task Force (1989) Acid rock drainage draft technical guide, Vol I and II. Report 66002/2, Prepared for the British Columbia AMD Task Force by SRK, Inc
Berger AC, Bethke CM, Krumhansl JL (2000) A process model of natural attenuation in drainage from a historic mining district. Appl Geochem 15:655–666
Bigham JM, Nordstrom DK (2000) Iron and aluminium hydroxyl-sulphates from acid sulphate waters. In: Alpers CN, Jambor JL, Nordstrom DK (eds) Sulphate minerals, crystallography, geochemistry and environmental significance. Mineralogical Society of America, Washington, D.C, Reviews in mineralogy and geochemistry, pp 351–403
Bigham JM, Schwertmann U, Traina SJ, Winland RL, Wolf M (1996) Schwertmannite and the chemical modeling of iron in acid sulfate waters. Geochim Cosmochim Acta 60(12):2111–2121
Bladh K (1982) The formation of goethite, jarosite and alunite during the weathering of sulphide-bearing felsic rocks. Econ Geol 77:176–184
Blowes DW (1997) The environmental effects of mine wastes: mapping and monitoring the mine environment paper 119. In: AG Gubins (eds) Proceedings of Exploration 97: Fourth Decennial International Conference on Mineral Exploration. pp 887–892
Blowes DW, Jambor JL (1990) the pore-water geochemistry and the mineralogy of the vadose zone of sulfide tailings, Waite Amulet, Quebec. App Geochem 5:327–346
Blowes DW, Ptacek CJ (1994) Acid-neutralization mechanisms in inactive Mine tailings. In: Jambor JL, Blowes DW (eds) Short course hand-book on environmental geochemistry of sulfide mine-wastes, vol 22. Mineralogical Association of Canada, Canada, pp 271–292
Boateng E, Dowuona GNN, Nude PM, Foli G, Gyekye P, Hashim M (2012) Geochemical assessment of the impact of mine tailings reclamation on the quality of soils at Anglogold concession, Obuasi, Ghana. Res J Environ Earth Sci 4(4):466–474
BS 1377 (1990) British Standard Institution: Methods of Test for soils for civil engineering purposes; Part 2, Classification tests p 62
Burton ED, Bush RT, Sullivan LA, Johnston SG, Hocking RK (2008) Mobility of arsenic and selected metals during re-flooding of iron- and organic-rich acid-sulfate soil. Chem Geol 253:64–73
Burton ED, Bush RT, Johnson SG, Watling KM, Horking RK, Sullivan LE, Parker GK (2009) Sorption of Arsenic (V) and Arsenic (III) to Scwertmannite: environ. Sci Technol 43:9202–9207
Carlson L, Bigham JM, Schwertmann U, Kyek A, Wagner F (2002) Scavenging of As from acid mine drainage by schwertmannite and ferrihydrite: a comparison with synthetic analogues. Environ Sci Technol 36(8):1712–1719
Casiot C, Lebrun S, Morin G, Bruneel O, Personne JC, Elbaz-Poulichet F (2005) Sorption and redox processes controlling arsenic fate and transport in a stream impacted by acid mine drainage. Sci Total Environ 347:122–130
Downing BW (2010) The management of analysis of ARD data. http://technology.infomine.com/enviromine/ard/Case%20Studies/data.html. Accessed 10 Oct 2012
Dunnivant FM, Jardine PM, Taylor DL, McCarthy JF (1992) Cotransport of cadmium and hexachlorobiphenyl by dissolved organic carbon through columns containing aquifer materials. Environ Sci Technol 26:360–368
Dzigbordi-Adjimah K (1993) Geology and geochemical patterns of the Birimian gold deposits, Ghana, West Africa. J Geochem Explor 47:305–320
EPA (2007) Monitored natural attenuation of inorganic contaminants in ground water. In: RG Ford, RT Wilkin, RW Puls (eds) Assessment for Non-Radionuclides Including Arsenic Cadmium Chromium Copper Lead Nickel Nitrate Perchlorate and Selenium vol 2. US Environmental Protection Agency Office of Research and Development National Risk Management Research Laboratory Ada, Oklahoma p 74820
Espana JS, Pamo EL, Pastor ES, Andres JR, Rubi JAM (2006) The removal of dissolved metals by hydroxysulphate precipitates during oxidation and neutralization of acid minewaters, Iberian Pyrite Belt. Aqua Geochem 12(3):269–298
Ferguson KD, Morin KA (1991) The Prediction of Acid Rock Drainage- Lessons From the Database. In: Second International Conference on the Abatement of Acidic Drainage, vol 1–4. Conference Proceedings, 16, 17, and 18 Sep 1991, Montreal
Foli G, Nude PM (2012) Concentration levels of some inorganic contaminants in streams and sediments in areas of pyrometallurgical and hydrometallurgical activities at the Obuasi mine. Environ Earth Sci, Ghana. doi:10.1007/s12665-011-1121-x.65:753-763
Foli G, Apeah OB, Amedjoe CG (2011) Pre-mining water quality prediction from non-weathered sulphide ores along the Ashanti Metallogenic belt in Ghana using Acid-Base accounting procedure. Am J Sci Ind Res Sci Huβ Am J Sci Ind Res 2–5:827–833
Foli G, Nude PM, Amedjoe CG, Kyei L (2012) Arsenic Leaching in Mill Tailings at the AngloGold Ashanti-Obuasi Mine, Ghana: management of contamination in the related water environment. West Africa J App Ecol 20(1):12–23
Foli G, Gawu SKY, Manu J, Nude PM (2013) Arsenic sorption characteristics in decommissioned tailings dam environment at the Obuasi mine Ghana. Res J Environ Earth Sci 5(10):599–610, ISSN: 2041-0484; e-ISSN: 2041–0492
Fukushi K, Sasaki M, Sato T, Yanase N, Amano H, Ikeda H (2003) A natural attenuation of arsenic in drainage from an abandoned arsenic mine dump. Appl Geochem 18(8):1267–1278
Gagliano WB, Brill MR, Bigham JM, Jones FS, Traina SJ (2004) Chemistry andmineralogy of ochreous sediments in a constructed mine drainage wetland. Geochim Cosmochim Acta 68(9):2119–2128
Garrels RM, Thompson ME (1960) Oxidation of pyrite by iron sulphate solution. Am J Sci 258A:656–668
Hall GEM (1992) Inductively coupled plasma mass spectrometry in geo-analysis. In: GEM Hall (eds) Geo-analysis, vol 44. J Geochemical Exploration pp 202–249
Hamric R, Miller V, Skousen J (2001) Proceedings, Sixteenth Annual Surface Mine Drainage Task Force. http://www.vmdtaskforce.com/proceedings/01/HAMRIC.PDF. Accessed on 31 Aug 2010
Helgeson (1970) A chemical and thermodynamic model of ore deposition in hydrothermal systems: mineralogy. Soc Am Spec Paper 3:155–186
Hernandez L, Probst A, Probst JL, Ulrich E (2003) Heavy metal distribution in some french forest soils: evidence for atmosphere contamination. Sci Total Environ 312:195–210
Hirdes W, Davis DW, Eisenlohr BN (1992) Reassessment of Proterozoic granitoids ages in Ghana on the basis of U/Pb zircon and monzonite dating. Precambr Res 56:89–96
Jeffery CH, Bassett Mendham J, Denny RC (eds) (1989) Vogel’s textbook of quantitative chemical analysis, 5th edn. Bash Press Ltd, UK, pp 477–479
Jönsson J, Persson P, Sjoberg S, Lovgren L (2005) Schwertmannite precipitated from acid mine drainage:phase transformation, sulphate release and surface properties. Appl Geochem 20(1):179–191
Joseph WL, Brady KBC, Perry EF (1994) Variation in computing acid base-accounting in the US Abstract In: International Land Reclamation and Mine Drainage Conference and Third International Conference on the Abatement of Acidic Drainage, US Bureau of Mines Special Publication SP 06B-94, p 417
Jurjovec J, Ptacek CJ, Blowes DW (2002) Acid neutralization mechanisms and metal release in mine tailings: a laboratory column experiment. Geochim Cosmochim Acta 66:1511–1523
Karamalidis AK, Voudrias EA (2009) Leaching and Immobilization Behavior of Zn and Cr from cement-based Stabilization/Solidification of Ash Produced from Incineration of refinery oily sludge. Environ Eng Sci 26(1):81–96
Kent DB, Davis JA, Anderson LCD, Rea BA (1995) Transport of chromium and selenium in a pristine sand and gravel aquifer: role of adsorption processes. Water Resour Res 31:1041–1050
Kesse GO (1985) Rock and m ineral resources of Ghana. Balkema, Amsterdam
Kuipers JR, Maest AS Mac-Hardy KA, Lawson G (2006) Comparison of predicted and actual water quality at hardrock mines: the reliability of predictions in environmental impact statements. Kuipers & Associates, PO Box 641, Butte, MT USA 5970 p 228
Kumpulainen S, Carlson L, Raisanen ML (2007) Seasonal variations of ochreous precipitates in mine effluents in Finland. Appl Geochem 22(4):760–777
Leblanc M, Achard B, Othman DB, Luck JM, Bertrand-Sarfati J, Personne JC (1996) Accumulation of Arsenic from acidic mine waters by ferruginous bacterial accretions (stromatolites). Appl Geochem 11(1996):541–554
Maest AS, Kuipers JR, Travers CL, Atkins DA (2005) Predicting water quality at hardrock mines: methods and models, uncertainties, and state-of-the-art. pp 42–50
Martin JM, Whitfield M (1983) The significance of the river inputs to the ocean. In: Wong CS, Boyle E, Bruland KW, Burton JD, Goldberg ED (eds) Trace metals in seawater. Plenum Press, New York
Mohiuddin KM, Zakir HM, Otomo K, Sharmin S, Shikazono N (2010) Geochemical distribution of trace metal pollutants in water and sediments of downstream of an urban river. Inter J Environ Sci Technol 7(1):17–28
Mukiibi M, Wilner (2009) US EPA’s TCLP Test Fails to Predict the Leaching Risk of Water Treatment Arsenic Residuals. (Spotlight); https://www.google.com.gh/search?q=azh2o.com/pdf/Mukiibi_Dec09. Accessed on 28 Aug 2013
Munk L, Faure G, Pride DE, Bigham JM (2002) Sorption of trace metals to an aluminum precipitate in a stream receiving acid rock-drainage; Snake River, Summit County, Colorado. Appl Geochem 17:421–430
Murad E, Rojik P (2005) Iron mineralogy of mine-drainage precipitates as environ-mental indicators: review of current concepts and a case study from the Sokolov Basin, Czech Republic. Clay Minerals 40(4):427–440
Norris CH (2005) Water quality impacts from remediating acid mine drainage with alkaline addition. http://www.catf.us/resources/publications/files/Norris_Arsenic_Report.pdf. Accessed on 25 Aug 2010
Oberthur T, Vetter U, Scmidt MA, Weiser T, Amanor JA, Gyapong WA, Kumi RK, Blenkinsop TG (1994) The Ashanti Gold mine at Obuasi, Ghana: Mineralogical, Geochemical, Stable Isotope and fluid inclusion studies on the metallogenesis of the deposit; Metallogenesis of Selected Gold Deposits in Africa pp 44–79, 101–113
Osae S, Kase K, Yamamoto M (1995) A geochemical study of the Ashanti gold deposit at Obuasi. Ghana Dept Earth Sci Faculty Sci OKAYAMA Univ Earth Sci Rep 2:81–90
Parkhurst DL, Appelo CAJ (1999) User’s guide to PHREEQC (version 2)—a computer program for speciation, batch reaction, one-dimentional transport, and inverse geochemical calculations, US Geological Survey. Water Resour Inv Rep 99–4259:312
Pedersen HD, Posma D, Jakobsen R (2006) Release of arsenic associated with the reduction and transformation of iron oxides. Geochim Cosmochim Acta 70:4116–4129
Peretyazhko T, Zachara JM, Boily JF, Xia Y, Gassman PL, Arey BW, Burgos WD (2009) Mineralogical transformations controlling acid mine drainage chemistry. US Department of Energy Publications, Paper 194; http://digitalcommonsunl.edu/usdoepub/194
Perry EF (1985) Overburden analysis: an evaluation of methods. p 369–375. In: Proceedings Symp. of Surface Mining, Hydrology, Sedimentology, and Reclamation, Lexington, p 12. 9–13 Dec 1985 OSC
Pile DL, Benjamin AS, Lackner KS, Wendt CH, Butt DP (1998) A precise methods for determining the CO2 content in carbonate materials. J Chem Edu LA-UR-97-1384
Praveena SM, Radojevic M, Abdullah MH (2007) The assessment of mangrove sediment quality in Mengkabong lagoon: an index analysis approach. Inter J Environ Sci Edu 2(3):60–68
Price W, Errington J (1994) ARD Policy for mine sites in British Columbia. Presented at International Land Reclamation and Mine Drainage Conference and the Third International Conference on the Abatement of Acid Drainage, Pittsburgh, PA, p 287
Regenspurg S, Peiffer S (2005) Arsenate and chromate incorporation in schwertmannite. Appl Geochem 20(6):1226–1239
Runnells DD, Shields MJ, Jones RL (1997) Methodology for adequacy of sampling of mill tailings and mine waste rock. In: AA Balkema (eds) Tailings and mine waste. Ft. Collins, CO: Rotterdam and Brookfield
Schwertmann U, Carlson L (2005) The pH-dependent transformation of schwertmannite to goethite at 25°C. Clay Miner 40(1):63–66
Shih K, Tang Y (2011) Prolonged toxicity characteristic leaching procedure for nickel and copper Aluminates†. J Environ Monitor 13:829–835
Smith A, Barton Bridges JB (1991) Some considerations in the prediction and control of AMD impact on groundwater from mining in North America: In: Proceeding of the EPPIC Water Symposium, Johannesburg, 16–17 May
Sobek A, Schuller W, Freeman JR, Smith RM (1978) Field and laboratory methods applicable to overburdens and mine soils: Prepared for US Environmental Protection Agency, Cincinnati: EPA-600/2-78-054, p 203
Spence RD (1993) Chemistry and microstructure of solidified waste forms. Lewis Pub, Ann Arbor
Stewart W, Miller S, Smart R, Gerson A, Thomas JE, Skinner W, Levay G, Schumann R (2003a) Evaluation of the Net Acid Generation (NAG) test for assessing the acid generating capacity of sulphide minerals. In: Proceedings of the Sixth International Conference on Acid Rock drainage (ICARD), Cairns, pp 617-625 12–18 Jul 2003
Svensson T, Lovett GM, Likens GE (2012) Is chloride a conservative ion in forest ecosystems? Biogeochemistry 107(1–3):125–134
Taylor SR (1964) Abundance of chemical elements in the continental crust: a new table. Geochim Cosmochim Acta 28:1273–1286
Taylor and McLennan (1981) The composition and evolution of the continental crust: rare earth element evidence from sedimentary rocks. Philos Trans R Soc Lond 301A:381–399
Taylor PN, Moorbath S, Leube A, Hirdes W (1992) Early Proterozoic crustal evolution in the Birimian of Ghana; constraints from geochronology and isotope geology. Precambr Res 56:77–111
TCLP Manual 1311:SW-846 (1992) Toxicity characteristic leaching procedure, p 38
Tulasi D, Adotey D, Affum A, Carboo D, Yaw Serfor-Armah Y (2013) Speciation of As(III) and As(V) in water and sediment using reverse-phase ion-pair high-performance liquid chromatography-neutron activation analysis (HPLC-NAA). Environ Monit Assess Environ Monit Assess. doi:10.1007/s10661-013-3148-9
Turekian KK, Wedepohl KH (1961) Distribution of the elements in some major units of the earth’s crust. Geol Soc Am Bull 72:175–192
USEPA (1989) Statistical Analysis of Groundwater Monitoring Data at RCRA Facilities, Interim Final Guidance and Draft Addendum to Interim Final Guidance (July 1992). EP A Office of Solid Waste, Washington, DC
Wang S, Mulligan CN (2006) Occurrence of arsenic contamination in Canada: sources, behavior, and distribution. Sci Total Environ 366:701–721
Windom HL (1988) A guide to the interpretation of metal concentrations in estuarine sediments. In: Steven JS (eds) Coastal Zone Management Section Florida Department of Environmental Regulation 2600 Blairstone Rd. Office of Water Policy, Florida Department of Environmental Protection 3900 Commonwealth Blvd. Tallahassee, pp 32399–3000
Acknowledgments
The authors acknowledge the Environmental Services Department of AngloGold Ashanti, Obuasi mine for their assistance in the laboratory work. Reviews by anonymous journal reviewers and comments by the journal editor are greatly appreciated.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Foli, G., Gawu, S.K.Y. & Nude, P.M. Arsenic contamination and secondary mineral evaluation in mine drainage using integrated acid–base accounting and toxicity characterisation leaching procedure: the case of Obuasi Mine, Ghana. Environ Earth Sci 73, 8471–8486 (2015). https://doi.org/10.1007/s12665-014-4006-y
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s12665-014-4006-y