Bioelectrochemical degradation of monoaromatic compounds: Current advances and challenges

[Display omitted] •Bioelectrochemical degradation of monoaromatic compounds (MACs) was summarized.•MACs include phenol, BTEX, chlorophenol, nitrobenzene and chloramphenicol.•Reactor configuration, electrode material, electroactive microbe are key factors.•Mediators, sulfur/hydrogen cycle, system par...

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Veröffentlicht in:Journal of hazardous materials 2020-11, Vol.398, p.122892, Article 122892
Hauptverfasser: Yang, Kaichao, Ji, Min, Liang, Bin, Zhao, Yingxin, Zhai, Siyuan, Ma, Zehao, Yang, Zhifan
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Sprache:eng
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Zusammenfassung:[Display omitted] •Bioelectrochemical degradation of monoaromatic compounds (MACs) was summarized.•MACs include phenol, BTEX, chlorophenol, nitrobenzene and chloramphenicol.•Reactor configuration, electrode material, electroactive microbe are key factors.•Mediators, sulfur/hydrogen cycle, system parameters also affect the process.•MACs bioelectrodegradation advantages are efficiency, selectivity and stability. Monoaromatic compounds (MACs) are typical refractory organic pollutants which are existing widely in various environments. Biodegradation strategies are benign while the key issue is the sustainable supply of electron acceptors/donors. Bioelectrochemical system (BES) shows great potential in this field for providing continuous electrons for MACs degradation. Phenol and BTEX (Benzene, Toluene, Ethylbenzene and Xylenes) can utilize anode to enhance oxidative degradation, while chlorophenols, nitrobenzene and antibiotic chloramphenicol (CAP) can be efficiently reduced to less-toxic products by the cathode. However, there still have several aspects need to be improved including the scale, electricity output and MACs degradation efficiency of BES. This review provides a comprehensive summary on the BES degradation of MACs, and discusses the advantages, future challenges and perspectives for BES development. Instead of traditional expensive dual-chamber configurations for MACs degradation, new single-chamber membrane-less reactors are cost-effective and the hydrogen generated from cathodes may promote the anode degradation. Electrode materials are the key to improve BES performance, approaches to increase the biofilm enrichment and conductivity of materials have been discussed, including surface modification as well as composition of carbon and metal-based materials. Besides, the development and introduction of functional microbes and redox mediators, participation of sulfur/hydrogen cycling may further enhance the BES versatility. Some critical parameters, such as the applied voltage and conductivity, can also affect the BES performance, which shouldn’t be overlooked. Moreover, sequential cathode-anode cascaded mode is a promising strategy for MACs complete mineralization.
ISSN:0304-3894
1873-3336
DOI:10.1016/j.jhazmat.2020.122892