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Delineating Landfill Leachate Discharge To An Arsenic Contaminated Waterway
Citation:
FORD, R. G., S. D. ACREE, B. K. LIEN, K. G. SCHECKEL, T. P. LUXTON, R. R. ROSS, A. G. Williams, AND P. J. CLARK. Delineating Landfill Leachate Discharge To An Arsenic Contaminated Waterway. H. Fiedler (ed.), CHEMOSPHERE. Elsevier Ltd, Oxford, Uk, 85(9):1525-1537, (2011).
Impact/Purpose:
The objectives of the work were to: 1) define the dimensions of the presumed contaminant plume discharging to a shallow cove within the pond, 2) determine the existence of chemical indicators for waste constituents to constrain identification of the plume origin, and 3) evaluate whether the flux of arsenic and other constituents transported by the plume were consistent with constituent concentrations measured in surface water within the discharge zone.
Description:
Discharge of contaminated ground water may serve as a primary and on-going source of contamination to surface water. A field investigation was conducted at a Superfund site in Massachusetts, USA to define the locus of contaminant flux and support source identification for arsenic contamination in a pond abutting a closed landfill. Subsurface hydrology and ground-water chemistry were evaluated in the aquifer between the landfill and the pond during the period 2005-2009 employing a network of wells to delineate the spatial and temporal variability in subsurface conditions. These observations were compared with concurrent measures of ground-water seepage and surface water chemistry within a shallow cove that had a historical visual record of hydrous ferric oxide precipitation along with elevated arsenic concentrations in shallow sediments. Barium, presumably derived from materials disposed in the landfill, served as an indicator of leachate-impacted ground water discharging into the cove. Evaluation of the spatial distributions of seepage flux and the concentrations of barium, calcium, and ammonium-nitrogen indicated that the identified plume primarily discharged into the central portion of the cove. Comparison of the spatial distribution of chemical signatures at depth within the water column demonstrated that direct discharge of leachate-impacted ground water was the source of highest arsenic concentrations observed within the cove. These observations demonstrate that restoration of the impacted surface water body will necessitate control of leachate-impacted ground water that continues to discharge into the cove.
