Magnetite nanoparticles accelerate the autotrophic sulfate reduction in biocathode microbial electrolysis cells

Magnetite nanoparticles accelerate the autotrophic sulfate reduction in biocathode microbial electrolysis cells

[Display omitted] •MEC with magnetite achieved 122% improvement in sulfate reduction.•Electron recovery efficiency in MEC with magnetite enhanced by 90%.•Biomass and microbial activity of biocathode increased with the magnetite effect.•MEC with magnetite had higher abundance of Desulfovibrio at bioc...

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Bibliographic Details
Published in:Biochemical engineering journal Vol. 133; pp. 96 - 105
Main Authors: Hu, Jiaping, Zeng, Cuiping, Liu, Guangli, Luo, Haiping, Qu, Lei, Zhang, Renduo
Format: Journal Article
Language:English
Published: Elsevier B.V 15-05-2018
Subjects:
Autotrophic biocathode
Cathode biofilm
Magnetite nanoparticles
Microbial electrolysis cell
Sulfate reduction
Microbial electrolysis cell
Sulfate reduction
Autotrophic biocathode
Magnetite nanoparticles
Cathode biofilm
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Summary:[Display omitted] •MEC with magnetite achieved 122% improvement in sulfate reduction.•Electron recovery efficiency in MEC with magnetite enhanced by 90%.•Biomass and microbial activity of biocathode increased with the magnetite effect.•MEC with magnetite had higher abundance of Desulfovibrio at biocathode. The aim of this study was to investigate the effect of magnetite nanoparticles on the performance of autotrophic sulfate-reducing biocathode in microbial electrolysis cell (MEC). The biocathodes in MECs were start-up using cathode medium with and without magnetite nanoparticles addition (with initial iron content of 0.64 mM), respectively. With magnetite, the sulfate reductive rate reached 152 ± 7.0 g m−3 d−1, which was improved by 122% than the MEC without magnetite. The electron recovery efficiencies in MECs with and without magnetite were 56.1% and 29.6%, respectively. With the effect of magnetite, the peak currents in cyclic voltammograms of the biocathode were about two times higher than that without magnetite, indicating its higher electrochemical activity. Analyses of the scanning electron microscope and the energy dispersive spectrometer showed that pilus-like substance and iron-sulfide were formed on the magnetite-biocathode. Confocal laser scanning microscopy showed the increase of the biomass, thickness, and viability of biofilm in the biocathode with magnetite compared to those without magnetite. The relative abundance of Desulfovibrio sp. was 72.2% in the biocathode with magnetite compared to 27.5% without magnetite. The conductive magnetite could affect the development of electrochemical active biofilm directly and accelerate sulfate reduction in the MEC.
ISSN:1369-703X
1873-295X
DOI:10.1016/j.bej.2018.01.036