TY - JOUR
T1 - Prediction of diffuse sulfate emissions from a former mining district and associated groundwater discharges to surface waters
AU - Graupner, B.J.
AU - Koch, C.B.
AU - Prommer, Henning
PY - 2014
Y1 - 2014
N2 - Rivers draining mining districts are often affected by the diffuse input of polluted groundwaters. The severity and longevity of the impact depends on a wide range of factors such as the source terms, the hydraulic regime, the distance between pollutant sources and discharge points and the dilution by discharge from upstream river reaches. In this study a deterministic multi-mine life-cycle model was developed. It is used to characterize pollutant sources and to quantify the resulting current and future effects on both groundwater and river water quality. Thereby sulfate acts as proxy for mining-related impacts. The model application to the Lausitz mining district (Germany) shows that the most important factors controlling concentrations and discharge of sulfate are mixing/dilution with ambient groundwater and the rates of biological sulfate reduction during subsurface transport. In contrast, future impacts originating from the unsaturated zones of the mining dumps showed to be of little importance due to the high age of the mining dumps and the associated depletion in reactive iron-sulfides. The simulations indicate that currently the groundwater borne diffuse input of sulfate into the rivers Kleine Spree and Spree is ~2200. t/years. Our predictions suggest a future increase to ~11,000. t/years within the next 40. years. Depending on river discharge rates this represents an increase in sulfate concentration of 40-300. mg/L. A trend reversal for the surface water discharge is not expected before 2050. © 2014 Elsevier B.V.
AB - Rivers draining mining districts are often affected by the diffuse input of polluted groundwaters. The severity and longevity of the impact depends on a wide range of factors such as the source terms, the hydraulic regime, the distance between pollutant sources and discharge points and the dilution by discharge from upstream river reaches. In this study a deterministic multi-mine life-cycle model was developed. It is used to characterize pollutant sources and to quantify the resulting current and future effects on both groundwater and river water quality. Thereby sulfate acts as proxy for mining-related impacts. The model application to the Lausitz mining district (Germany) shows that the most important factors controlling concentrations and discharge of sulfate are mixing/dilution with ambient groundwater and the rates of biological sulfate reduction during subsurface transport. In contrast, future impacts originating from the unsaturated zones of the mining dumps showed to be of little importance due to the high age of the mining dumps and the associated depletion in reactive iron-sulfides. The simulations indicate that currently the groundwater borne diffuse input of sulfate into the rivers Kleine Spree and Spree is ~2200. t/years. Our predictions suggest a future increase to ~11,000. t/years within the next 40. years. Depending on river discharge rates this represents an increase in sulfate concentration of 40-300. mg/L. A trend reversal for the surface water discharge is not expected before 2050. © 2014 Elsevier B.V.
U2 - 10.1016/j.jhydrol.2014.03.045
DO - 10.1016/j.jhydrol.2014.03.045
M3 - Article
SN - 0022-1694
VL - 513
SP - 169
EP - 178
JO - Journal of Hydrology
JF - Journal of Hydrology
ER -