Abstract
Hard and brown coal mining has a long tradition in central and eastern Europe and covers large areas of mining in Germany, Poland and the Czech Republic (Geller et al., this Vol.). In Germany there are three main districts of lignite surface mining: the Rheinish district near Cologne, the mid-German district around Leipzig and the Lusatian district around Cottbus in the most eastern part of Germany. Surface mining of lignite (brown coal) results in several environmental problems, for example important disturbances of the natural water balance, mass transfer of billions of tons of soil and devastation of nature. Among these, water acidification is an already well-known effect. Sulphide minerals, such as pyrite and marcasite, are commonly associated with coal and most metal ores. Weathering and oxidation of these minerals take place in the host rocks and substrates of the lignite horizons when they are exposed to air. The release of the oxidation products, mainly acidity, iron and sulphate, is known as acid mine drainage (AMD) and has been the subject of intense research for decades (e. g. Singer and Stumm 1970; Lowsen 1982; Nordstrom 1982; van Berk 1987; Morrison et al. 1990; Blowes et al. 1991, Hedin et al. 1994; Wisotzky 1994).
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References
Appelo CAJ, Postma D (1993) Geochemistry, groundwater and pollution. Balkema, Rotterdam
Belzile N, Morris JR (1995) Lake sediments: sources or sinks of industrially mobilized elements. In: Gunn JM (ed) Restoration and recovery of an industrial region. Springer, New York Berlin Heidelberg, pp 183–193
Benndorf J (1994) Sanierungsmaßnahmen in Binnengewässern: Auswirkungen auf die trophische Struktur. Limnologica 24: 121–135
Blowes DW, Reardon EJ, Jambor JL, Cherry JA (1991) The formation and potential importance of cemented layers in inactive sulfide mine tailings. Geochim Cosmo- chim Acta 55: 965–978
DEV-Deutsche Einheitsverfahren zur Wasser-, Abwasser- und Schlamm-Untersuchung (1991) FG Wasserchemie der GDCh, Normenausschuß Wasserwesen, DIN Deutsches Institut für Normung (Hrsg.) 25 Lfg.VCH, Weinheim
Hamilton-Taylor J, Davison W (1995) Redox-driven cycling of trace elements in lakes. In: Lerman A, Imboden D, Gat J (eds) Physics and chemistry of lakes, 2nd edn. Springer, Berlin Heidelberg New York, pp 217–263
Hedin RS, Narin RW, Kleinmann LP (1994) Passive treatment of coal mine drainage. United States Department of the Interior, Bureau of Mines, Information Circular 1994, Pittsburgh, pp 1–35
Klapper H, Schultze M (1995) Geogenically acidified mining lakes - living conditions and possibilities of restoration. Int Rev Ges Hydrobiol 80: 639–653
Klapper H, Geller W, Schultze M (1996) Abatement of acidification in mining lakes in Germany. Lakes Reservoirs Res Manage 2: 7–16
Lowsen RT (1982) Aqueous oxidation of pyrite by molecular oxygen. Chem Rev 82: 461–497
Morrison JL, Scheetz BE, Strickler DW, Williams EG, Rose AW, Davis A, Parizk R (1990) Predicting the occurrence of acid mine drainage in the Alleghenian coal- bearing strata of western Pennsylvania: an assessment by simulated weathering (leaching) experiments and overburden characterisation. Geol Soc Am Spec Pap 248: 87–99
Nixdorf B, Rücker J, Köcher B, Deneke R (1995) Erste Ergebnisse zur Limnologie von Tagebaurestseen in Brandenburg unter besonderer Berücksichtigung der Besiedlung im Pelagial. In: Geller W, Packroff G (Hrsg) Abgrabungsseen - Risiken und Chancen. Limnologie aktuell 7. Gustav-Fischer, Stuttgart, S 39–52
Nordstrom DK (1982) Aqueous pyrite oxidation and the consequent formation of secondary iron minerals. In: Kittrick JA (ed) Acid sulphate weathering. Soil Sci Soc Am Spec Publ 10: 37–57
Pietsch W (1979) Zur hydrochemischen Situation der Tagebauseen des Lausitzer Braunkohlen-Reviers. Arch Naturschutz Landschaftsforsch Berl 19: 97–115
Salomons W, Förstner U (1984) Metals in the hydrocycle. Springer, Berlin Heidelberg New York
Schultze M, Geller W (1996): The acid lakes of lignite mining district of the former German Democratic Republic. In: Reuther R (ed) Geochemical approaches to environmental engineering of metals. Environmental Science Series. Springer, Berlin Heidelberg New York, pp 89–105
Singer PC, Stumm W (1970) Acid mine drainage: rate-determining step. Science 167: 1121–1123
Stumm W, Morgan JJ (1981) Aquatic chemistry, 2nd edn. Wiley, New York
Uhlmann D, Hupfer M, Paul L (1995) Longitudinal gradients in the chemical and microbial composition of the bottom sediment in a channel reservoir ( Saidenbach R., Saxony). Int Rev Ges Hydrobiol 80: 15–25
Van Berk W (1987) Hydrochemische Stoffumsetzungen in einem Grundwasserleiter beeinflußt durch eine Steinhohlenbergehalde. Besondere Mitteilungen zum Dtsch Gewässerkdl Jahrb 49: 1–175
Wisotzky F (1994) Untersuchungen zur Pyritoxidation in Sedimenten des Rheinischen Braunkohlenreviers und deren Auswirkungen auf die Chemie des Grundwassers. Besondere Mitteilungen zum Dtsch Gewässerkdl Jahrb 58: 1–153
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Friese, K., Hupfer, M., Schultze, M. (1998). Chemical Characteristics of Water and Sediment in Acid Mining Lakes of the Lusatian Lignite District. In: Geller, W., Klapper, H., Salomons, W. (eds) Acidic Mining Lakes. Environmental Science. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-71954-7_3
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DOI: https://doi.org/10.1007/978-3-642-71954-7_3
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