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AuthorGunda, Mohanakrishna
AuthorAbu Reesh, Ibrahim M.
AuthorVanbroekhoven, Karolien
AuthorPant, Deepak
Available date2022-09-05T10:06:16Z
Publication Date2020-05-01
Publication NameScience of The Total Environment
Identifierhttp://dx.doi.org/10.1016/j.scitotenv.2020.137003
CitationMohanakrishna, G., Reesh, I. M. A., Vanbroekhoven, K., & Pant, D. (2020). Microbial electrosynthesis feasibility evaluation at high bicarbonate concentrations with enriched homoacetogenic biocathode. Science of The Total Environment, 715, 137003.‏
ISSN00489697
URIhttps://www.sciencedirect.com/science/article/pii/S0048969720305131
URIhttp://hdl.handle.net/10576/33688
AbstractAn enrichment methodology was developed for a homoacetogenic biocathode that is able to function at high concentrations of bicarbonates for the microbial electrosynthesis (MES) of acetate from carbon dioxide. The study was performed in two stages; enrichment of consortia in serum bottles and the development of a biocathode in MES. A homoacetogenic consortium was sequentially grown under increasing concentrations of bicarbonate, in serum bottles, at room temperature. The acetate production rate was found to increase with the increase in the bicarbonate concentration and evidenced a maximum production rate of 260 mg/L d−1 (15 g HCO3−/L). On the contrary, carbon conversion efficiency decreased with the increase in the bicarbonate concentration, which evidenced a maximum at 2.5 g HCO3−/L (90.16%). Following a further increase in the bicarbonate concentration up to 20 g HCO3−/L, a visible inhibition was registered with respect to the acetate production rate and the carbon conversion efficiency. Well adapted biomass from 15 g HCO3−/L was used to develop biocathodic catalyst for MES. An effective biocathode was developed after 4 cycles of operation, during which acetate production was improved gradually, evidencing a maximum production rate of 24.53 mg acetate L−1 d−1 (carbon conversion efficiency, 47.72%). Compared to the enrichment stage, the carbon conversion efficiency and the rate of acetate production in MES were found to be low. The production of acetate induced a change in the catholyte pH, from neutral conditions towards acidic conditions.
Languageen
PublisherElsevier Ltd
SubjectMicrobial electrosynthesis (MES)
Carbon concentration
Bicarbonates
Catholyte pH
Biocathode
TitleMicrobial electrosynthesis feasibility evaluation at high bicarbonate concentrations with enriched homoacetogenic biocathode
TypeArticle
Volume Number715
dc.accessType Abstract Only


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