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« Previous AbstractSoli-gas measurement for detection of groundwater contamination by volatile organic compounds    Next AbstractTritrophic interactions follow phylogenetic escalation and climatic adaptation »

J Environ Monit


Title:The use of isotopes to identify landfill gas effects on groundwater
Author(s):Kerfoot HB; Baker JA; Burt DM;
Address:"GeoSyntecConsultants, 2100 Main Street, Huntington Beach, CA 92646, USA. hkerfoot@geosyntec.com"
Journal Title:J Environ Monit
Year:2003
Volume:5
Issue:6
Page Number:896 - 901
DOI: 10.1039/b310351j
ISSN/ISBN:1464-0325 (Print) 1464-0325 (Linking)
Abstract:"An evaluation of the source of volatile organic compounds in groundwater samples was performed at a landfill in southern California. The 3H (tritium) content of the water in leachate and water from the gas-collection system (condensed water and entrained water droplets) and the delta 13C and 14C content of the inorganic carbon in landfill gas CO2, leachate, and gas-collection system water were used to characterize the dissolved inorganic carbon (DIC) inside the landfill, while the same parameters were monitored in groundwater samples from affected monitoring wells and an unaffected well. Tritium levels from leachate and gas-collection system condensate ranged from approximately 2000 TU to over 4000 TU, orders of magnitude higher than unaffected groundwater. The average 14C content of DIC in the landfill pore-water samples was 121 pMC and the 14C content of unaffected groundwater DIC was 93 pMC, while the 14C content of the dissolved inorganic carbon in groundwater with VOC detections ranged from 105 to 119 pMC. The delta 13C of DIC in pore water was consistently above 0 per thousand and the delta 13C of unaffected groundwater DIC was -20.3 per thousand, while the delta 13C of DIC in affected groundwater samples was increased from -17.3 to -13.2 per thousand. The increases in both delta 13C and 14C in landfill gas-impacted groundwater DIC generally correlated with the number of volatile organic compounds detected and their concentrations. Based on the tritium and DIC 14C levels in leachate and water from the gas-collection system compared to those of unaffected water, significant increases in the tritium content of the water would be expected to accompany VOC detections and increases in delta 13C and 14C caused by landfill water. The results rule out landfill water as the VOC source, leaving landfill gas as the source. The identities and concentrations of the specific VOCs in affected groundwater samples varied among wells as well as between two leachate samples, ruling out the use of a VOC 'fingerprint' for leachate or landfill gas to be compared to groundwater VOC concentrations"
Keywords:"Carbon Isotopes/analysis Carbon Radioisotopes/analysis Environmental Monitoring/methods Gases/analysis Hydrocarbons/*analysis *Refuse Disposal Soil Pollutants/*analysis Tritium/*analysis Volatilization Water Pollutants, Chemical/*analysis;"
Notes:"MedlineKerfoot, Henry B Baker, John A Burt, David M eng England 2004/01/09 J Environ Monit. 2003 Dec; 5(6):896-901. doi: 10.1039/b310351j"

 
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