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Simultaneous dairy wastewater treatment and bioelectricity production in a new microbial fuel cell using photosynthetic Synechococcus / Tratamiento simultáneo de aguas residuales lácteas y producción de bioelectricidad en una nueva celda de combustible microbiana utilizando Synechococcus fotosintético
Khodadi, Sahar; Karbassi, Abdolreza; Tavakoli, Omid; Baghdadi, Majid; Zare, Zeinab.
Affiliation
  • Khodadi, Sahar; University of Tehran. College of Engineering. School of Environment. Tehran. Iran
  • Karbassi, Abdolreza; University of Tehran. College of Engineering. School of Environment. Tehran. Iran
  • Tavakoli, Omid; University of Tehran. College of Engineering. Faculty of Chemical Engineering. Tehran. Iran
  • Baghdadi, Majid; University of Tehran. College of Engineering. School of Environment. Tehran. Iran
  • Zare, Zeinab; University of Tehran. College of Engineering. Faculty of Chemical Engineering. Tehran. Iran
Int. microbiol ; 26(4): 741-756, Nov. 2023. ilus
Article in En | IBECS | ID: ibc-227467
Responsible library: ES1.1
Localization: ES15.1 - BNCS
ABSTRACT
Photosynthetic microbial fuel cell (PMFC) is a novel technology, which employs organic pollutants and organisms to produce electrons and biomass and capture CO2 by bio-reactions. In this study, a new PMFC was developed based on Synechococcus sp. as a biocathode, and dairy wastewater was used in the anode chamber. Different experiments including batch feed mode, semi-continuous feed mode, Synechococcus feedstock to the anode chamber, Synechococcus-Chlorella mixed system, the feedstock of treated wastewater to the cathode chamber, and use of extra nutrients in the anodic chamber were performed to investigate the behavior of the PMFC system. The results indicated that the PMFC with a semi-continuous feed mode is more effective than a batch mode for electricity generation and pollutant removal. Herein, maximum power density, chemical oxygen demand removal, and Coulombic efficiency were 6.95 mW/m2 (450 Ω internal resistance), 62.94, and 43.16%, respectively, through mixing Synechococcus sp. and Chlorella algae in the batch-fed mode. The maximum nitrate and orthophosphate removal rates were 98.83 and 68.5%, respectively, wherein treated wastewater in the anode was added to the cathode. No significant difference in Synechococcus growth rate was found between the cathodic chamber of PMFC and the control cultivation cell. The heating value of the biocathode biomass at maximum Synechococcus growth rate (adding glucose into the anode chamber) was 0.2235 MJ/Kg, indicating the cell’s high ability for carbon dioxide recovery. This study investigated not only simultaneous bioelectricity production and dairy wastewater in a new PMFC using Synechococcus sp. but also studied several operational parameters and presented useful information about their effect on PMFC performance.(AU)
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Collection: 06-national / ES Database: IBECS Main subject: Bioelectric Energy Sources / Chlorella / Biomass / Synechococcus / Electricity / Calorific Power Language: En Journal: Int. microbiol Year: 2023 Document type: Article
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Collection: 06-national / ES Database: IBECS Main subject: Bioelectric Energy Sources / Chlorella / Biomass / Synechococcus / Electricity / Calorific Power Language: En Journal: Int. microbiol Year: 2023 Document type: Article