Hostname: page-component-586b7cd67f-r5fsc Total loading time: 0 Render date: 2024-11-25T08:12:10.283Z Has data issue: false hasContentIssue false

Cycling of As, P, Pb and Sb during weathering of mine tailings: implications for fluvial environments

Published online by Cambridge University Press:  05 July 2018

D. Kossoff
Affiliation:
Department of Earth and Planetary Sciences, Birkbeck, University of London, Malet Street, London WC1E 7HX, UK Department of Earth Sciences, The Natural History Museum, Cromwell Road, London SW7 5BD, UK
K. A. Hudson-Edwards*
Affiliation:
Department of Earth and Planetary Sciences, Birkbeck, University of London, Malet Street, London WC1E 7HX, UK
W. E. Dubbin
Affiliation:
Department of Earth Sciences, The Natural History Museum, Cromwell Road, London SW7 5BD, UK
M. Alfredsson
Affiliation:
School of Physical Sciences, Ingram Building, University of Kent, Canterbury CT2 7NH, UK
T. Geraki
Affiliation:
Diamond Light Source, Didcot, Oxfordshire OX11 0DE, UK
*

Abstract

The weathering and oxidation of mine tailings has the potential to contaminate water and soil with toxic elements. To understand the mechanisms, extent and products of the long-term weathering of complex Bolivian tailings from the Cerro Rico de Potosí, and their effects on As, Pb, P and Sb cycling, three-year long laboratory column experiments were carried out to model 20 years of dry- and wet-season conditions in the Pilcomayo basin. Chemical analysis of the leachate and column solids, optical mineralogy, X-ray diffraction, scanning electron microscopy, electron probe microanalysis, microscale X-ray absorption near edge structure spectroscopy, Bureau Commun de Référence sequential extraction and water-soluble chemical extractions, and speciation modelling have shown that the weathering of As-bearing pyrite and arsenopyrite, resulted in a loss of 13–29% of the original mass of As. By contrast, Pb and Sb showed much lower mass losses (0.1–1.1% and 0.6–1.9%, respectively) due to the formation of insoluble Pb- and Sb(V)-rich phases, which were stable at the low pH (~2) conditions that prevailed by the end of the experiment. The experiment also demonstrated a link between the cycling of As, Sb, and the oxidation of Fe(II)-bearing sphalerite, which acted as a nucleation point for an Fe-As-Sb-O phase. Phosphorus was relatively immobile in the tailings columns (up to 0.3% mass loss) but was more mobile in the soil-bearing columns (up to 10% mass loss), due to the formation of soluble P-bearing minerals or mobilization by organic matter. These results demonstrate the influence of mine tailings on the mobility of P from soils and on the potential contamination of ecosystems with As, and strongly suggest that these materials should be isolated from fluvial environments.

Type
Research Article
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 2016

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Abollino, O., Giacomino, A., Malandrino, M. and Mentasti, E. (2008) Interaction of metal ions with montmorillonite and vermiculite. Applied Clay Science, 38, 227236.CrossRefGoogle Scholar
Ake, C., Mayura, K., Huebner, H., Bratton, G. and Phillips, T. (2001) Development of porous claybased composites for the sorption of lead from water. Journal of Toxicology and Environmental Health Part A, 63, 459475.CrossRefGoogle ScholarPubMed
Archer, J., Hudson-Edwards, K.A., Preston, D.A., Howarth, R.J. and Linge, K. (2005) Aqueous exposure and uptake of arsenic by riverside communities affected by mining contamination in the Rio Pilcomayo basin, Bolivia. Mineralogical Magazine, 69, 719736.CrossRefGoogle Scholar
Arp, P.A. and Meyer, W.L. (1985) Formation constants for selected organo-metal (Al3+, Fe3+)-phosphate complexes. Canadian Journal of Chemistry, 63, 33573366.CrossRefGoogle Scholar
Atkins, P.W. (1995) Physical Chemistry. Oxford University Press, Oxford, UK.Google Scholar
Benjamin, M. and Leckie, J. (1981) Multiple-site adsorption of Cd, Cu, Zn, and Pb on amorphous iron oxyhydroxide. Journal of Colloid and Interface Science, 79, 209221.CrossRefGoogle Scholar
Bethke, C. (1996) Geochemical Reaction Modelling: Concepts and Applications. Oxford University Press, New York, 397 pp.CrossRefGoogle Scholar
Bigham, J.M., Carlson, L. and Murad, E. (1994) Schwertmannite, a new iron oxyhydroxysulphate from Pyhäsalmi, Finland, and other localities. Mineralogical Magazine, 58, 641648.CrossRefGoogle Scholar
Biver, M. and Shotyk, W. (2012) Stibnite (Sb2S3) oxidative dissolution kinetics from pH 1 to 11. Geochimica et Cosmochimica Acta, 79, 127139.CrossRefGoogle Scholar
Blanchard, M., Alfredsson, M., Brodholt, J., Wright, K. and Catlow, C.R.A. (2006) Arsenic incorporation into FeS2 pyrite and its influence on dissolution: a DFT study. Geochimica et Cosmochimica Acta, 71, 624630.CrossRefGoogle Scholar
Bolton, K. (1996) Corrosion. Open University, Milton Keynes, UK.Google Scholar
Cheng, H., Hu, Y., Luo, J., Xu, B. and Zhao, J. (2009) Geochemical processes controlling fate and transport of arsenic in acid mine drainage (AMD) and natural systems. Journal of Hazardous Materials, 165, 1326.CrossRefGoogle ScholarPubMed
Craw, D., Falconer, D. and Youngson, J.H. (2003) Environmental arsenopyrite stability and dissolution: theory, experiment, and field observations. Chemical Geology, 199, 7182.CrossRefGoogle Scholar
Cunningham, C., McNamee, J., Pinto, V. and Ericksen, G.E. (1991) A model of volcanic dome-hosted precious metal deposits in Bolivia. Economic Geology, 86, 415421.CrossRefGoogle Scholar
Davidson, C.M., Duncan, A.L., Littlejohn, D., Ure, A.M. and Garden, L.M. (1998) A critical evaluation of the three-stage BCR sequential extraction procedure to assess the potential mobility and toxicity of heavy metals in industrially-contaminated land. Analytica Chimica Acta, 363, 4555.CrossRefGoogle Scholar
Delaney, J.M. and Lundeen, S.R. (1990) The LLNL Thermodynamic Database. Lawrence Livermore National Laboratory Report UCRL-21658. Lawrence Livermore National Laboratory, Livermore, California, USA.Google Scholar
Diemar, G.A., Filella, M., Leverett, P. and Williams, P.A. (2009) Dispersion of antimony from oxidizing ore deposits. Pure and Applied Chemistry, 81, 15471553.CrossRefGoogle Scholar
Doménech, C., de Pablo, J. and Ayora, C. (2002) Oxidative dissolution of pyritic sludge from the Aznalcó llar mine (SW Spain). Chemical Geology, 190, 339353.CrossRefGoogle Scholar
Fawcett, W.E. and Jamieson, H.E. (2011) The distinction between ore processing and post-depositional transformation on the speciation of arsenic and antimony in mine waste and sediment. Chemical Geology, 283, 109118.CrossRefGoogle Scholar
Filella, M., Williams, P.A. and Belzile, N. (2009a) Antimony in the environment: knowns and unknowns. Environmental Chemistry, 6, 95105.CrossRefGoogle Scholar
Filella, M., Philippo, S., Belzile, N., Chen, Y. and Quentel, F. (2009b) Natural attenuation processes applying to antimony: a study in the abandoned antimony mine in Goesdorf, Luxembourg. Science of the Total Environment, 407, 62056216.CrossRefGoogle Scholar
Forray, F.L., Smith, A.M.L., Drouet, C., Navrotsky, A., Wright, K., Hudson-Edwards, K.A. and Dubbin, W.E. (2010) Synthesis, characterization and thermochemistry of a Pb-jarosite. Geochimica et Cosmochimica Acta, 74, 215224.CrossRefGoogle Scholar
Foster, A.L., Brown, G.E. Jr, Tingle, T.N. and Parks, G.A. (1998) Quantitative arsenic speciation in mine tailings using X-ray absorption spectroscopy. American Mineralogist, 83, 553568.CrossRefGoogle Scholar
Foy, R. and Withers, P. (1995) The contribution of agricultural phosphorus to eutrophication. Proceeding of the International Fertiliser Society, no. 365, 32 pp.Google Scholar
Fu, Z., Wu, F., Amarasiriwardena, D., Mo, C., Liu, B., Zhu, J., Deng, Q. and Liao, H. (2010) Antimony, arsenic and mercury in the aquatic environment and fish in a large antimony mining area in Hunan, China. Science of the Total Environment, 408, 34033410.CrossRefGoogle Scholar
Gaboreau, S., Beaufort, D., Vieillard, P., Patrier, P. and Bruneton, P. (2005) Aluminum phosphate-sulfate minerals associated with Proterozoic unconformitytype uranium deposits in the East Alligator River uranium field, Northern Territories, Australia. The Canadian Mineralogist, 43, 813827.CrossRefGoogle Scholar
He, M. (2007) Distribution and phytoavailability of antimony at an antimony mining and smelting area, Hunan, China. Environmental Geochemistry and Health, 29, 209219.CrossRefGoogle ScholarPubMed
Hochella, M.F. Jr, Moore, J.N., Golla, U. and Putnis, A. (1999) A TEM study of samples from acid mine drainage systems: metal-mineral association with implications for transport. Geochimica et Cosmochimica Acta, 63, 33953406.CrossRefGoogle Scholar
Hudson-Edwards, K.A., Macklin, M.G., Miller, J.R. and Lechler, P.J. (2001) Sources, distribution and storage of heavy metals in the Río Pilcomayo, Bolivia. Journal of Geochemical Exploration, 72, 229250.CrossRefGoogle Scholar
Hudson-Edwards, K.A., Macklin, M.G., Jamieson, H.E., Brewer, P.A., Coulthard, T.J., Howard, A.J. and Turner, J. (2003) The impact of tailings dam spills and clean-up operations on sediment and water quality in river systems: the Ríos Agrio-Guadiamar, Aznalcó llar, Spain. Applied Geochemistry, 18, 221239.CrossRefGoogle Scholar
Hudson-Edwards, K.A., Jamieson, H.E., Charnock, J.M. and Macklin, M.G. (2005) Arsenic speciation in waters and sediment of ephemeral floodplain pools, Ríos Agrio-Guadiamar, Aznalcó llar, Spain. Chemical Geology, 219, 175192.CrossRefGoogle Scholar
Jambor, J.L., Nordstrom, D.K. and Alpers, A.N. (2000) Metal-sulfate salts from sulfide mineral oxidation. Pp. 303350 in: Sulfate Minerals. Crystallography, Geochemistry and Environmental Significance (C.N. Alpers J.L. Jambor and D.K. Nordstrom, editors). Reviews in Mineralogy and Geochemistry, 40. Mineralogical Society of America, Washington DC and the Geochemical Society, St Louis, Missouri. USA.Google Scholar
Jamieson, H.E., Robinson, C., Alpers, A.N., McCleskey, R.B., Nordstrom, D.K. and Peterson, R.C. (2005) Major and trace element composition of copiapitegroup minerals and coexisting water from the Richmond mine, Iron Mountain, California. Chemical Geology, 215, 387405.CrossRefGoogle Scholar
Jimnez-Cáceles, F.J. and Á varez-Rógel, J. (2008) Phosphorus fractionation and distribution in salt marsh soils affected by mine wastes, and eutrophicated water: a case study in SE Spain. Geoderma, 144, 299309.CrossRefGoogle Scholar
Kossoff, D., Hudson-Edwards, K.A., Dubbin, W.E. and Alfredsson, M.A. (2011) Incongruent weathering of Cd and Zn from mine tailings: a column leaching study. Chemical Geology, 281, 5271.CrossRefGoogle Scholar
Kossoff, D., Hudson-Edwards, K.A., Dubbin, W.E. and Alfredsson, M. (2012) Major and trace metal mobility during weathering of mine tailings: implications for floodplain soils. Applied Geochemistry, 27, 562576.CrossRefGoogle Scholar
Leverett, P., Reynolds, J.K., Roper, A.J. and Williams, P.A. (2012) Tripuhyite and schafarzikite: two of the ultimate sinks for antimony in the natural environment. Mineralogical Magazine, 76, 891902.CrossRefGoogle Scholar
Macklin, M., Payne, I., Preston, D. and Sedgwick, C. (1996) Review of the Porco Mine Tailings Dam Burst and Associated Mining Waste Problems, Pilcomayo Basin, Bolivia. Report to UK Overseas Development Administration. University of Wales, Aberystwyth, UK.Google Scholar
Majzlan, J., Lalinská, B., Chovan, M., Bläb, U., Brecht, B., Gö ttlicher, J., Steininger, R., Hug, K., Ziegler, S. and Gescher, J. (2011) A mineralogical, geochemical, and microbiological assessment of the antimony- and arsenic-rich neutral mine drainage tailings near Pezinok, Slovakia. American Mineralogist, 96, 113.CrossRefGoogle Scholar
Mihaljevic, M., Ettler, V., Sebek, O., Drahota, P., Strnad, L., Procházka, R., Zeman, J. and Sracek, O. (2009) Alteration of arsenopyrite in soils under different vegetation covers. Science of the Total Environment, 408, 12861294.CrossRefGoogle ScholarPubMed
Miller, J.R. and Orbock Miller, S.M. (2007) Contaminated Rivers: A Geomorphological- Geochemical Approach to Site Assessment and Remediation. Springer, London.CrossRefGoogle Scholar
Miller, J.R., Hudson-Edwards, K.A., Lechler, P.J., Preston, D. and Macklin, M.G. (2004) Heavy metal contamination of water, soil and produce within riverine communities of the Río Pilcomayo basin, Bolivia. Science of the Total Environment, 320, 189209.CrossRefGoogle ScholarPubMed
Mitsu Mineral Development Engineering Company (1999) The Study on Evaluation of Environmental Impact of Mining Sector in Potosi Prefecture of the Republic of Bolivia. Mitsu Mineral Development Engineering Co. Ltd. and Unico International Corporation.Google Scholar
Morris, J.C. and Stumm, W. (1967) Redox equilibria and measurements of potentials in the aquatic environment. Pp. 270285 in: Equilibrium Concepts in Natural Water Systems (W. Stumm, editor). Advances in Chemistry, 67. American Chemical Society, Washington DC.CrossRefGoogle Scholar
Nordstrom, D.K. and Archer, D.G. (2003) Arsenic thermodynamic data and environmental geochemistry. Pp. 116 in: Arsenic in Ground Water (A.H. Welch and K.G. Stollenwerk, editors). Kluwer Academic Publishers, Boston, USA.Google Scholar
Papirer, E. (2000) Adsorption on Silica Surfaces. Marcel Dekker, New York.CrossRefGoogle Scholar
Pruvot, C., Douay, F., Herve, F. and Waterlot, C. (2006) Heavy metals in soil, crops and grass as a source of human exposure in the former mining areas. Journal of Soils and Sediments, 6, 215220.CrossRefGoogle Scholar
Ravel, B. and Newville, M. (2005) ATHENA, ARTEMICS, HEPHAESTUS: data analysis for Xray absorption spectroscopy using IFEFFIT. Journal of Synchrotron Radiation, 12, 537541.CrossRefGoogle Scholar
Roussel, C., Néel, C. and Bril, H. (2000) Minerals controlling arsenic and lead solubility in an abandoned gold mine tailings. Science of the Total Environment, 263, 209219.CrossRefGoogle Scholar
Schreiber, M., Simo, J. and Freiberg, P. (2000) Stratigraphic and geochemical controls on naturally occurring arsenic in groundwater, eastern Wisconsin, USA. Hydrogeology Journal, 8, 161176.CrossRefGoogle Scholar
Shannon, R.D. (1976) Revised effective ionic radii and systematic studies of interatomic distances in halides and chalcogenides. Acta Crystallographica, A32, 751767.CrossRefGoogle Scholar
Smart, L. and Gagan, M. (2002) The Third Dimension. The Open University, Milton Keynes, UK.Google Scholar
Smedley, P., Edmunds, W. and Pelig-Ba, K. (1996) Mobility of arsenic in groundwater in the Obuasi gold-mining area of Ghana: some implications for human health. Geological Society London Special Publication, 113, 163181.CrossRefGoogle Scholar
Søvik, A.K. and Køve, B. (2005) Phosphorus retention processes in shell sand filter systems treating municipal wastewater. Ecological Engineering, 25, 168182.CrossRefGoogle Scholar
Stallard, R.F. and Edmond, J.M. (1981) Geochemistry of the Amazon: 1. Precipitation chemistry and the marine contribution to the dissolved load at the time of peak discharge. Journal of Geophysical Research, 86, 98449858.CrossRefGoogle Scholar
Strosnider, W.H. and Nairn, R.W. (2010) Effective passive treatment of high-strength acid mine drainage and raw municipal wastewater in Potosí, Bolivia using simple mutual incubations and limestone. Journal of Geochemical Exploration, 105, 3442.CrossRefGoogle Scholar
Strosnider, W.H.J., Llanos López, F.S. and Nairn, R.W. (2011a) Acid mine drainage at Cerro Rico de Potosí I: unabated high-strength discharges reflect a five century legacy of mining. Environmental Earth Sciences, 64, 899910.CrossRefGoogle Scholar
Strosnider, W.H.J., Llanos López, F.S. and Nairn, R.W. (2011b) Acid mine drainage at Cerro Rico de Potosí II: severe degradation of the upper Rio Pilcomayo watershed. Environmental Earth Sciences, 64, 911923.CrossRefGoogle Scholar
Tenderholt, A., Hedman, B. and Hodgson, K.O. (2007) PySpline: a modern, cross-platform program for the processing of raw averaged XAS edge and EXAFS data. AIP Conference Proceedings (XAFS13), 882, 105107.CrossRefGoogle Scholar
Tighe, M., Ashley, P., Lockwood, P. and Wilson, S. (2005) Soil, water, and pasture enrichment of antimony and arsenic within a coastal floodplain system. Science of the Total Environment, 347, 175186.CrossRefGoogle ScholarPubMed
Vink, B.W. (1996) Stability relations of antimony and arsenic compounds in the light of revised and extended Eh-pH diagrams. Chemical Geology, 130, 2130.CrossRefGoogle Scholar
West, A.R. (1991) Basic Solid State Chemistry. John Wiley & Sons, Chichester, UK.Google Scholar
Wilkie, J. and Hering, J. (1996) Adsorption of arsenic onto hydrous ferric oxide: effects of adsorbate/ adsorbent ratios and co-occurring solutes. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 107, 97110.CrossRefGoogle Scholar
Wilson, S.C., Lockwood, P.V., Ashley, P.M. and Righe, M. (2010) The chemistry and behaviour of antimony in the soil environment with comparisons to arsenic: a critical review. Environmental Pollution, 158, 11691181.CrossRefGoogle ScholarPubMed
Younger, P. and Wolkersdorfer, C. (2004) Mining impacts on the fresh water environment: technical and managerial guidelines for catchment scale management. Mine Water and Environment, 23, 280.CrossRefGoogle Scholar