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The micro-niche of exoelectrogens influences bioelectricity generation in bioelectrochemical systems

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  • Yan, Xuejun
  • Lee, Hyung-Sool
  • Li, Nan
  • Wang, Xin

Abstract

Bioelectrochemical systems (BESs) employ exoelectrogens to degrade organic matter, and produce value-added products, such as bioelectricity, methane, acetate and hydrogen. Based on the advantages of energy saving and resource recovery, BES is expected to play an important role in sustainable wastewater treatment in the future. Although considerable progress has been made in the past two decades, the commercialization of BES still needs to overcome many technical challenges to reduce costs and increase electricity output. A comprehensive understanding of the working mechanism of exoelectrogens rooted in the defined micro-niche that covers interactions with electrolytes, electrodes and other microorganisms, is the premise of solving the problem. To provide theoretical guidance for BES performance optimization, this review summarized the defined micro-niche of exoelectrogens in BES, including the overall set environmental conditions of BES and the local microenvironment of electroactive biofilms (EABs). With the expansion of EAB, the microenvironment of EAB slightly shifts in pH gradient, metabolic activity, electron transfer pathways and synergetic growth with other microorganisms. Exoelectrogens in different niche have different contributions to current, and this can be adjusted by optimization of substrate, electrode material, electrode potential, etc. In summary, an efficient and stable micro-niche is the key to ensure that BES continues to produce bioelectricity and remove pollutants, providing guidance for BES design and operation in the future.

Suggested Citation

  • Yan, Xuejun & Lee, Hyung-Sool & Li, Nan & Wang, Xin, 2020. "The micro-niche of exoelectrogens influences bioelectricity generation in bioelectrochemical systems," Renewable and Sustainable Energy Reviews, Elsevier, vol. 134(C).
    • Handle: RePEc:eee:rensus:v:134:y:2020:i:c:s1364032120304743
    DOI: 10.1016/j.rser.2020.110184
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    1. Dianne K. Newman & Roberto Kolter, 2000. "A role for excreted quinones in extracellular electron transfer," Nature, Nature, vol. 405(6782), pages 94-97, May.
    2. Chatterjee, Pritha & Dessì, Paolo & Kokko, Marika & Lakaniemi, Aino-Maija & Lens, Piet, 2019. "Selective enrichment of biocatalysts for bioelectrochemical systems: A critical review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 109(C), pages 10-23.
    3. Gemma Reguera & Kevin D. McCarthy & Teena Mehta & Julie S. Nicoll & Mark T. Tuominen & Derek R. Lovley, 2005. "Extracellular electron transfer via microbial nanowires," Nature, Nature, vol. 435(7045), pages 1098-1101, June.
    4. Arthur Prindle & Jintao Liu & Munehiro Asally & San Ly & Jordi Garcia-Ojalvo & Gürol M. Süel, 2015. "Ion channels enable electrical communication in bacterial communities," Nature, Nature, vol. 527(7576), pages 59-63, November.
    5. Rebecca J. Steidl & Sanela Lampa-Pastirk & Gemma Reguera, 2016. "Mechanistic stratification in electroactive biofilms of Geobacter sulfurreducens mediated by pilus nanowires," Nature Communications, Nature, vol. 7(1), pages 1-11, November.
    6. Jintao Liu & Arthur Prindle & Jacqueline Humphries & Marçal Gabalda-Sagarra & Munehiro Asally & Dong-yeon D. Lee & San Ly & Jordi Garcia-Ojalvo & Gürol M. Süel, 2015. "Metabolic co-dependence gives rise to collective oscillations within biofilms," Nature, Nature, vol. 523(7562), pages 550-554, July.
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