Electrolytic Methanogenic−Methanotrophic Coupling for Tetrachloroethylene Bioremediation: Proof of Concept

Coupling of methanogenic and methanotrophic catabolisms was performed in a single-stage technology equipped with a water electrolysis cell placed in the effluent recirculation loop. The electrolysis-generated hydrogen served as an electron donor for both bicarbonate reduction into CH4 and reductive...

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Bibliographic Details
Published in:Environmental science & technology 2008-04, Vol.42 (8), p.3011-3017
Main Authors: Guiot, Serge R, Cimpoia, Ruxandra, Kuhn, Ramona, Alaplantive, Aude
Format: Article
Language:English
Subjects:
Anaerobiosis
Applied sciences
Bicarbonate
Biodegradation, Environmental
Bioreactors
Bioremediation
Chemistry
Electrolysis
Exact sciences and technology
Kinetics
Methane - metabolism
Mineralization
Oxygen - metabolism
Pollution
Remediation and Control Technologies
Tetrachloroethylene - metabolism
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Summary:Coupling of methanogenic and methanotrophic catabolisms was performed in a single-stage technology equipped with a water electrolysis cell placed in the effluent recirculation loop. The electrolysis-generated hydrogen served as an electron donor for both bicarbonate reduction into CH4 and reductive dechlorination, while the O2 and CH4, supported the cometabolic oxidation of chlorinated intermediates left over by the tetrachloroethylene (PCE) transformation. The electrolytical methanogenic/methanotrophic coupled (eMaMoC) process was tested in a laboratory-scale setup at PCE loads ranging from 5 to 50 µmol/Lrx·d (inlet concentrations from 4 to 11 mg/L), and at various hydraulic residence times (HRT). Degradation followed essentially a reductive dechlorination pathway from PCE to cis-1,2-dichloroethene (DCE), and an oxidative pathway from DCE to CO2. PCE reductive dechlorination to DCE was consistently over 98% while a maximum oxidative DCE mineralization of 89% was obtained at a load of 4.3 µmol PCE/Lrx·d and an HRT of 6 days. Controlling dissolved oxygen concentrations within a relatively low range (2–3 mg/L) seemed instrumental to sustain the overall degradation capacity. Degradation kinetics were further evaluated: the apparent half-saturation constant (K S) had to be set relatively high (29 µM) for the simulated data to best fit the experimental ones. In spite of such kinetic limitations, the eMaMoC system, while fueled by water electrolysis, was effective in building and sustaining a functional methanogenic/methanotrophic consortium capable of significant PCE mineralization in a single-stage process. Hence, degradation standards are within reach so long as the methanotrophic DCE-oxidizing potential, including substrate affinity, are optimized and HRT accordingly adjusted.
ISSN:0013-936X
1520-5851
DOI:10.1021/es702121u