Laboratory scale microcosm studies were conducted using site specific
groundwater and aquifer solids to assess the feasibility of stimulating indigenous
microorganisms in-situ to biologically transform Trichloroethylene (TCE) and its lesser
chlorinated daughter products dichloroethylene (DCE) and vinyl chloride (VC). Three
different treatments were conducted to determine the best approach for biologically
remediating TCE under site specific conditions: anaerobic reductive dechlorination,
aerobic cometabolism and sequential anaerobic/aerobic stimulation. Studies were
conducted in batch serum bottles containing aquifer solids, groundwater and a gas
headspace.
Long-term (302 days) TCE anaerobic reductive dechlorination studies compared
lactate, benzoate and methanol as potential anaerobic substrates. Site characteristic
sulfate concentrations in the microcosms averaged 1,297 mg/L and TCE was added to
levels of 2.3 mg/L. Substrates were added at one and a half times the stoichiometric
electron equivalent of sulfate. Nutrient addition and bioaugmentation were also studied.
Both benzoate and lactate stimulated systems achieved complete sulfate-reduction and
prolonged dechlorination of TCE to VC and ethylene. Dechlorination was initiated
between 15 to 20 days following lactate utilization and sulfate-reduction in the presence
of approximately 300 mg/L sulfate. Benzoate amended microcosms did not initiate dechlorination until 120 to 160 days following the complete removal of available sulfate. After 302 days of incubation lactate and benzoate amended microcosms completely transformed TCE to VC with 7 to 15% converted to ethylene. Re-additions of TCE into both systems resulted in its rapid transformation to VC. The dechlorination of VC to ethylene was very slow and appeared to be dependent on VC concentration. Hydrogen addition at 10����� and 10������ atmospheres had no effect on the transformation of VC. Rapid methanol utilization resulted in its nearly stoichiometric conversion to methane and carbon dioxide without significant sulfate-reduction or dechlorination occurring. Nutrient addition slightly enhanced dehalogenation with lactate but inhibited it with benzoate. Bioaugmentation with a TCE dechlorinating culture from a previous benzoate amended Point Mugu microcosm effectively decreased lag-times and increased overall dechlorination.
Aerobic cometabolism studies evaluated methane, phenol and propane as cometabolic growth substrates. Methane and phenol amended microcosms were able to remove only 50 to 60% of the added TCE after four stimulations, while propane utilizers were unable to cometabolize any TCE. Primary substrate utilization lag-times of 4 to 5 days, 0 to 0.5 days and 40 to 45 days were observed for methane, phenol and propane, respectively. Cometabolism of VC was possible in the presence of methane. Complete removal of 210 ��g/L VC was achieved after 2 stimulations with methane under strictly aerobic conditions. Methane utilization and VC oxidation required nitrate addition, indicating that the system was nitrate limited. A sequential anaerobic/aerobic microcosm study failed to achieve methane utilization and VC transformation likely due to oxygen being utilized to re-oxidize reduced sulfate in the system. / Graduation date: 1999
Identifer | oai:union.ndltd.org:ORGSU/oai:ir.library.oregonstate.edu:1957/33320 |
Date | 23 November 1998 |
Creators | Keeling, Matthew Thomas |
Contributors | Semprini, Lewis |
Source Sets | Oregon State University |
Language | en_US |
Detected Language | English |
Type | Thesis/Dissertation |
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