Bioelectrochemical approach for reductive and oxidative dechlorination of chlorinated aliphatic hydrocarbons (CAHs)

A sequential reductive-oxidative treatment was developed in this study in a continuous-flow bioelectrochemical reactor to address bioremediation of groundwater contaminated by trichloroethene (TCE) and less-chlorinated but still harmful intermediates, such as vinyl chloride. In order to optimize the...

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Bibliographic Details
Published in:Chemosphere (Oxford) 2017-02, Vol.169, p.351-360
Main Authors: Lai, Agnese, Aulenta, Federico, Mingazzini, Marina, Palumbo, Maria Teresa, Papini, Marco Petrangeli, Verdini, Roberta, Majone, Mauro
Format: Article
Language:English
Subjects:
Biodegradation, Environmental
Bioreactors
Bioremediation
Chlorinated solvents
Electrodes
Graphite - chemistry
Groundwater - analysis
Groundwater - chemistry
Halogenation
MMO anodes
Oxidation-Reduction
Oxidative dechlorination
Oxides
Oxygen - chemistry
Silicon Dioxide - chemistry
Titanium - chemistry
Trichloroethylene - chemistry
Vinyl Chloride - chemistry
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Summary:A sequential reductive-oxidative treatment was developed in this study in a continuous-flow bioelectrochemical reactor to address bioremediation of groundwater contaminated by trichloroethene (TCE) and less-chlorinated but still harmful intermediates, such as vinyl chloride. In order to optimize the anodic compartment, whereby the oxygen-driven microbial oxidation of TCE-daughter products occurs, abiotic batch experiments were performed with various anode materials poised at +1.20 V vs. SHE (i.e., graphite rods and titanium mesh anode coated with mixed metal oxides (MMO)) and setups (i.e., electrodes embedded within a bed of silica beads or graphite granule). The MMO anode displayed higher efficiency (>90%) for oxygen generation compared to the graphite electrodes. Additionally, the graphite bed presence adversely affects oxygen generation, likely due to the oxygen scavenging. This effect was completely eliminated by replacing the graphite granules with silica beads. The anodic setups were thereafter verified in a mentioned reactor at an applied TCE loading rate of approximately 20 μM d−1 and a hydraulic retention time of 1.4 d in each compartment. The cathode consisted of a bed of graphite granules and was potentiostatically controlled at −0.65 V vs. SHE. The best reactor performance in terms of removal efficiency (i.e., >97%), removal rate (i.e., 121.8 ± 2.7 μeq L−1 d−1), and the residual concentration (i.e., 5.03 ± 0.63 μeq L−1) of chlorinated contaminants was achieved with the MMO anode placed in a silica bed. Ecotoxicity tests performed with algae confirmed these results by showing progressive toxicity reduction from inlet to cathodic and anodic effluent using this reactor configuration. •A cathode-anode flow-through bioelectrochemical reactor is used for effective CAHs bioremediation.•The mixed metal oxide (MMO) electrode is used to stimulate anodic oxidative dechlorination.•Graphite present in the anode hinders oxygen production decreasing oxidation yield.•Oxygen back-diffusion not affects the cathodic reductive dechlorination.•Ecotoxicity tests show progressive toxicity reduction from inlet to anodic effluent.
ISSN:0045-6535
1879-1298
DOI:10.1016/j.chemosphere.2016.11.072