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The stable isotopic geochemistry of the sulfur and carbon cycles in a modern karst environment

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Böttcher,  Michael E.
Department of Biogeochemistry, Max Planck Institute for Marine Microbiology, Max Planck Society;

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Citation

Böttcher, M. E. (1999). The stable isotopic geochemistry of the sulfur and carbon cycles in a modern karst environment. Isotopes in Environmental and Health Studies, 35(1-2), 39-61. doi:10.1080/10256019908234078.


Cite as: https://hdl.handle.net/21.11116/0000-0005-47CE-4
Abstract
The stable isotopic geochemistry of the sulfur and carbon cycles in a modern karst environment at the southwest border of the Hart Mountains (Germany) has been studied during a 7-year period. Beside major, minor and trace elements, river and sulfate-carbonate ground water were analyzed for the C-13/C-12 ratios of the dissolved carbonate species, the O-18/O-16 ratio of water, and the S-34/S-32 and O-18/O-16 ratios of dissolved sulfate. Additionally, the carbon, sulfur and oxygen isotopic composition of the major karst aquifers (carbonate and gypsum/anhydrite rocks) of the Permian Zechstein formation was measured. Nowadays, the stable isotope biogeochemistry of the river and karst water in the studied area results from the complex interactions between dissolution of biogenic CO2 in the water-unsaturated zone, (minor) subterrestrial microbial decomposition reactions of organic matter (recent DOC or fossil organic matter), interactions with carbonate and sulfate aquifer minerals, and input of acids from atmospheric pollution (e.g., sulfuric acid). Subsurface precipitation of secondary calcite due to the incongruent dissolution of gypsum and/or dolomite is deduced from the hydrogeochemical composition of selected ground waters and the isotopical composition of calcite found in gypsum aquifer material. Spring and river waters were additionally influenced by the liberation of carbon dioxide into the Earth's atmosphere, a process which is accompanied by the preferrential desorbtion of (CO2)-C-12. The sulfur isotopic composition of dissolved sulfate from ground and spring waters indicates a mixture of sulfate derived from surface waters (mainly originating from atmospheric pollution) and geogenic sulfate from the subsurface dissolution of gypsum/anhydrite of the Zechstein formation. The oxygen isotopic composition of dissolved sulfate is generally far away from the exchange equilibrium with water, but consistent with the two-component mixing model derived from the sulfur isotope ratios.