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Iron mineralogy of mine-drainage precipitates as environmental indicators: review of current concepts and a case study from the Sokolov Basin, Czech Republic

Published online by Cambridge University Press:  09 July 2018

E. Murad*
Affiliation:
Bayerisches Landesamt für Umwelt, Leopoldstrasse 30, D-95603 Marktredwitz, Germany
P. Rojík
Affiliation:
Sokolovská uhelná, a.s., Jednoty 1628, CZ-35645 Sokolov, Czech Republic

Abstract

Mine-drainage waters and associated precipitates from several active and abandoned lignite mines and mine dumps in the Sokolov Basin, northwestern Czech Republic, were sampled and analysed. The data showed considerable variations of effluent composition and pH that can generally be related to differences in the local microenvironments. Temporal changes such as seasonal fluctuations of precipitation, leading to variations of water infiltration through and runoff over mines and mine dumps, were also observed to noticeably affect effluent composition. These variations have led to a wide range of precipitates, the principal constituents of which are generally one or several of the ferric minerals jarosite, schwertmannite, goethite, ferrihydrite and lepidocrocite.

The present paper consists of two parts: a short review of the genesis and properties of the named minerals, and a study of mine-drainage precipitates formed under different local conditions in various lignite mines and mine dumps of the Sokolov mining district. We show that variations in mine-drainage precipitate mineralogy, such as the presence or absence of specific ‘key’ minerals, can serve as indicators for factors such as the pH and sulphate concentration, and thus — with certain limitations — for the genetic environment during precipitate formation. Such variations in composition are reflected, among other properties, in the precipitate colour, which can therefore be used for a rapid identification and classification — both in the field and by remote sensing — of regions that are potentially prone to acid mine drainage.

Type
Research Article
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 2005

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References

Bigham, J.M. & Murad, E. (1997) Mineralogy of ochre deposits formed by the oxidation of iron sulfide minerals. Pp. 193–225 in: Soils and Environment: Soil Processes from Mineral to Landscape Scale (Auerswald, K., Stanjek, H. & Bigham, J.M., editors). Advances in GeoEcology, 30, Catena-Verlag, Reiskirchen, Germany.Google Scholar
Bigham, J.M., Schwertmann, U. & Carlson, L. (1992) Mineralogy of precipitates formed by the biogeochemical oxidation of Fe(II) in mine drainage. Pp. 219–232 in: Biomineralization Processes of Iron and Manganese - Modern and Ancient Environments (Skinner, H.G.W. & Fitzpatrick, R.W., editors). Catena Supplement, 21, Catena-Verlag, Cremlingen-Destedt, Germany.Google Scholar
Bigham, J.M., Schwertmann, U., Traina, S.J., Winland, R.L. & Wolf, M. (1996) Schwertmannite and the chemical modelling of iron in acid sulfate waters. Geochimica et Cosmochimica Acta, 60, 2111–2121.Google Scholar
Bishop, J.L. & Murad, E. (1996) Schwertmannite on Mars? Spectroscopic analyses of schwertmannite, its relationship to other ferric minerals, and its possible presence in the surface material on Mars. Pp. 337–358 in: Mineral Spectroscopy: A Tribute to Roger G. Burns (Dyar, M.D., McCammon, C. & Schaefer, M.W., editors). Special Publication No. 5, The Geochemical Society, Houston, Texas.Google Scholar
Bouška, V. & Pešek, J. (1999) Distribution of elements in the world lignite average and its comparison with lignite seams of the North Bohemian and Sokolov Basins. Folia Musei Naturalium Bohemiae Occidentalis, Geologica, 42, 3–50.Google Scholar
Buckby, T., Black, S., Coleman, M.L. & Hodson, M.E. (2003) Fe-sulphate-rich evaporite mineral precipitates from the Rio Tinto, southwest Spain. Mineralogical Magazine, 67, 263–278.Google Scholar
Cornell, R.M. & Schwertmann, U. (2003) The Iron Oxides. Structure, Properties, Reactions, Occurrences and Uses, 2nd edition. Wiley-VCH, Weinheim, Germany, 664 pp.Google Scholar
Davis, R.A. Jr., Welty, A.T., Borrego, J., Morales, J.A., Pendon, J.G. & Ryan, J.G. (2000) Rio Tinto Estuary (Spain): 5000 years of pollution. Environmental Geology, 39, 1107–1116.Google Scholar
Fukushi, K., Sasaki, M., Sato, T., Yanase, N., Amano, H. & Ikeda, H. (2003) A natural attenuation of arsenic indrainage from an abandoned arsenic mine dump. Applied Geochemistry, 18, 1267–1278.CrossRefGoogle Scholar
Jönsson, J., Persson, P., Sjöberg, S. & Lövgren, L. (2005) Schwertmannite precipitated from acid mine drainage: phase transformation, sulphate release and surface properties. Applied Geochemistry, 20, 179–191.Google Scholar
Murad, E. & Bishop, J.L. (2000) The infrared spectrum of synthetic akaganéite, β-FeOOH. American Mineralogist, 85, 716–721.Google Scholar
Murad, E. & Cashion, J. (2004) Mössbauer Spectroscopy of Environmental Materials and their Industrial Utilization. Springer, Boston/Norwell , Massachusetts, USA, 418 pp.Google Scholar
Murad, E. & Rojík, P. (2003) Iron-rich precipitates in a mine drainage environment: influence of pH on mineralogy. American Mineralogist, 88, 1915–1918.Google Scholar
Murad, E. & Rojík, P. (2004) Jarosite, schwertmannite, goethite, ferrihydrite and lepidocrocite: the legacy of coal and sulfide ore mining. SuperSoil 2004: 3rd Australian New Zealand Soils Conference, December 2004, University of Sydney, Australia. Published on CD-ROM.Google Scholar
Murad, E., Bigham, J.M., Bowen, L.H. & Schwertmann, U. (1990) Magnetic properties of iron oxides produced by bacterial oxidation of Fe2+ under acid conditions. Hyperfine Interactions, 58, 2373–2376.CrossRefGoogle Scholar
Murad, E., Schwertmann, U., Bigham, J.M. & Carlson, L. (1994) Mineralogical characteristics of poorly crystallized precipitates formed by oxidation of Fe2+ in acid sulfate waters. Pp. 190–200 in: Environmental Geochemistry of Sulfide Oxidation (Alpers, C.N. & Blowes, D.W., editors). ACS Symposium Series 550, American Chemical Society, Washington, D.C.Google Scholar
Regenspurg, S., Brand, A. & Peiffer, S. (2004) Formation and stability of schwertmannite in acidic mining lakes. Geochimica et Cosmochimica Acta, 68, 1185–1197.Google Scholar
Rojík, P., Galek, R. & Pasšava, J. (1998) Sokolov Lignite Basin. Pp. 1–69 in: Excursion Guide, 8th Coal Geology Conference, Faculty of Sciences, Charles University, Prague.Google Scholar
Scheinost, A.C. & Schwertmann, U. (1999) Color identification of iron oxides and hydroxysulfates: use and limitations. Soil Science Society of America Journal, 63, 1463–1471.Google Scholar
Schwertmann, U. (1985) The effect of pedogenic environments on iron oxide minerals. Advances in Soil Science, 1, 171–200.Google Scholar
Schwertmann, U. & Cornell, R.M. (2000) Iron Oxides in the Laboratory. Preparation and Characterization, 2nd edition. Wiley-VCH, Weinheim, Germany, 188 pp.Google Scholar
Schwertmann, U. & Fitzpatrick, R.W. (1977) Occurrence of lepidocrocite and its association with goethite in Natal soils. Soil Science Society of America Journal, 41, 1013–1018.Google Scholar
Schwertmann, U., Bigham, J.M. & Murad, E. (1995) The first occurrence of schwertmannite in a natural stream environment. European Journal of Mineralogy, 7, 547–552.CrossRefGoogle Scholar
Stanjek, H. & Friedrich, R. (1986) The determination of layer charge by curve-fitting of Lorentz- and polarization-corrected X-ray diagrams. Clay Minerals, 21, 183–190.Google Scholar
Swayze, G.A., Smith, K.S., Clark, R.N., Sutley, S.J., Pearson, R.M., Vance, J.S., Hageman, P.L., Briggs, P.H., Meier, A.L., Singleton, M.J. & Roth, S. (2000) Using imaging spectrometry to map acidic mine waste. Environmental Science and Technology, 34, 47–54.Google Scholar
Williams, D.J., Bigham, J.M., Cravotta, C.A. III, Traina, S.J., Anderson, J.E. & Lyon, J.G. (2002) Assessing mine drainage pH from the color and spectral reflectance of chemical precipitates. Applied Geochemistry, 17, 1273–1286.Google Scholar