TY - JOUR
T1 - Hydrochemistry and hydrogen sulfide generating processes in the Malm aquifer, Bavarian Molasse Basin, Germany
AU - Mayrhofer, Christina
AU - Niessner, Reinhard
AU - Baumann, Thomas
N1 - Funding Information:
Geothermal exploration of the Malm aquifer in the Bavarian Molasse Basin is very active with a focus on the area around Munich where nine geothermal projects are already operating successfully and a dozen new projects are in progress. The geothermal wells extend into the Malm aquifer which is located between 1,500 and 5,500 m below ground surface. Typical production rates of the geothermal wells are in the range of 30–150 L/s and the production temperatures reach up to 160 °C. There was no a priori information about the hydrochemical conditions as the geothermal wells were, and still are, the first sampling points in this area. Nevertheless, the hydrochemical composition of the Malm groundwater is as important as the hydraulic conditions, because of precipitation and corrosion issues, and safety concerns arising from the presence of significant gas concentrations; therefore a screening and monitoring program was launched with financial support from the German Federal Ministry for the Environment, Nature Conservation and Nuclear Safety. Within the scope of this study, five geothermal projects with nine wells in the central basin underwent detailed hydrochemical and isotopic analysis and gas phase characterization.
Funding Information:
Financial support by the Federal Ministry for the Environment, Nature Conservation and Nuclear Safety is gratefully acknowledged. We also would like to thank our project partners FU Berlin, Germany (coordinator), Erdwerk GmbH, Munich, Germany, and LfU Bayern, Munich, Germany for their support and D. Kirste for his very helpful suggestions during the review process.
PY - 2014/2
Y1 - 2014/2
N2 - Knowledge about the hydrochemical conditions of deep groundwater is crucial for the design and operation of geothermal facilities. In this study, the hydrochemical heterogeneity of the groundwaters in the Malm aquifer, Germany, is assessed, and reasons for the extraordinarily high H2S concentrations in the central part of the Bavarian Molasse Basin are proposed. Samples were taken at 16 sites, for a total of 37 individual wells, to analyze cations, anions, gas loading and composition. The hydrochemical characteristics of the Malm groundwater in the center of the Molasse Basin are rather heterogeneous. Although the groundwater in the central basin is dominated by meteoric waters, there is a significant infiltration of saline water from higher strata. Care has to be taken in the interpretation of data from geothermal sites, as effects of chemical stimulation of the boreholes may not be fully removed before the final analyses. The distribution of H2S in the gas phase is correlated to the gas loading of the water which increases in the central basin. Temperatures, isotopic data and the sulfur mass balance indicate that H2S in the central basin is related to thermochemical sulfate reduction (south of Munich) and bacterial sulfate reduction (north of Munich).
AB - Knowledge about the hydrochemical conditions of deep groundwater is crucial for the design and operation of geothermal facilities. In this study, the hydrochemical heterogeneity of the groundwaters in the Malm aquifer, Germany, is assessed, and reasons for the extraordinarily high H2S concentrations in the central part of the Bavarian Molasse Basin are proposed. Samples were taken at 16 sites, for a total of 37 individual wells, to analyze cations, anions, gas loading and composition. The hydrochemical characteristics of the Malm groundwater in the center of the Molasse Basin are rather heterogeneous. Although the groundwater in the central basin is dominated by meteoric waters, there is a significant infiltration of saline water from higher strata. Care has to be taken in the interpretation of data from geothermal sites, as effects of chemical stimulation of the boreholes may not be fully removed before the final analyses. The distribution of H2S in the gas phase is correlated to the gas loading of the water which increases in the central basin. Temperatures, isotopic data and the sulfur mass balance indicate that H2S in the central basin is related to thermochemical sulfate reduction (south of Munich) and bacterial sulfate reduction (north of Munich).
KW - Carbonate rocks
KW - Geothermal
KW - Germany
KW - Hydrochemistry
KW - Thermal conditions
UR - http://www.scopus.com/inward/record.url?scp=84905732241&partnerID=8YFLogxK
U2 - 10.1007/s10040-013-1064-2
DO - 10.1007/s10040-013-1064-2
M3 - Article
AN - SCOPUS:84905732241
SN - 1431-2174
VL - 22
SP - 151
EP - 162
JO - Hydrogeology Journal
JF - Hydrogeology Journal
IS - 1
ER -