Modelling ion composition in seepage water from a column experiment with an open cut coal mine sediment |
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Authors: | B. Ludwig J. Prenzel P. Obermann |
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Affiliation: | 1. Institute of Soil Science and Forest Nutrition, University of Göttingen, Büsgenweg 2, 37077 Göttingen, Germany;2. Institute of Applied Geology, University of Bochum, Universitätsstr. 150, 44801 Bochum, Germany |
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Abstract: | Secondary reactions occurring in pyrite-containing sediments from open cut coal mines are complex and not fully understood. In this study, the changes in seepage water composition in a column experiment with a sediment containing pyrite (5.6 g kg−1) were evaluated using a chemical equilibrium model. A column experiment with artificial irrigation (730 mm water yr−1) was carried out for 2 yr with a sediment from the open pit mine Garzweiler, Germany, at the Institute of Applied Geology. Tracer (LiCl) was added to the sediment. Seepage water composition at 52 cm depth was sampled weekly. Redox potential and the water potential were also recorded weekly. Sulphate and Fe(II) were the dominant ions in the seepage water with concentration maxima of 500 and 350 mmol l−1 after 50 days (0.7 pore volumes (PV)). Minimum pH values were around 0.8 after 100 days (1.4 PV), but increased subsequently and reached 2.4 after 700 days (9.5 PV). Ion activity product calculations indicated the intermediate formation of gypsum (19th–480th day of the experiment). Solutions were undersaturated with respect to alunite, jarosite, jurbanite, schwertmannite, melanterite, gibbsite and goethite during the whole experiment. The model of coupled equilibria which included inorganic complexation, precipitation/dissolution of gypsum and multiple cation exchange was tested. Pyrite oxidation and pH-dependent silicate weathering were considered using simple input functions. Transport was modelled using a field capacity cascade submodel. Model results showed satisfactory agreement with measured values for pH and concentrations of SO4, Fe, Mg, Ca and Al. Correlation coefficients lay between 0.7 and 0.9 and linear regression coefficients (modelled against measured) were 1.5 (Ca), 1.0 (Fe, SO4), 0.8 (Mg), 0.7 (pH) and 0.6 (Al). The results showed that the protons produced during pyrite oxidation (94 mmolc H+ kg−1) were mainly released into seepage water (as HSO4− and H+). Cation exchange reactions buffered 20 mmolc of H+ kg−1 sediment, and Al released by silicate weathering accounted for 3.6 mmolc H+ kg−1. Modelling was useful to further understand the significance of different pH buffer reactions. |
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Keywords: | cation exchange column experiment equilibrium model gypsum kinetics pyrite seepage silicate weathering transport |
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