Addition of carbon dioxide enhances electrical power production in a microbial reverse electrodialysis cell

Carbon dioxide utilization technology is essential for achieving carbon neutrality. In this study, we propose a promising method to produce renewable electricity and improve wastewater treatability and system stability by simply dissolving carbon dioxide in a microbial reverse electrodialysis cell (...

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Bibliographic Details
Published in:Journal of water process engineering 2024-12, Vol.68, p.106475, Article 106475
Main Authors: Kim, Eojin, Kang, Heunggu, Koo, Bonyoung, Pandit, Soumya, Lee, Myoung Jin, Jung, Sokhee P.
Format: Article
Language:English
Subjects:
Bicarbonate buffer
Carbon capture and utilization
Carbon dioxide
Greenhouse gas
Microbial reverse electrodialysis cell
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Summary:Carbon dioxide utilization technology is essential for achieving carbon neutrality. In this study, we propose a promising method to produce renewable electricity and improve wastewater treatability and system stability by simply dissolving carbon dioxide in a microbial reverse electrodialysis cell (MRC). MRC is an environmental energy system that combines a microbial fuel cell and a reverse electrodialysis stack. Increasing the bicarbonate buffer concentrations in the anolyte and the catholyte improved power generation, reduced internal resistances, and improved energy recovery and treatability. The MRC with the 200 mM-bicarbonate anolyte and 200 mM-bicarbonate catholyte produced 5124 mW m−2 at 7636 mA m−2 with 127-Ω internal resistance, 32 % energy efficiency, 25 % coulombic efficiency and 36 COD-mg (L·h)−1. Both the anolyte buffer and catholyte buffer are important in MRC performance, but the anolyte buffer had the greater impact than the catholyte buffer. After the MRC operation, all the anolyte conductivities increased, but it was not the case in the catholyte. The anolyte improved energy and coulombic efficiencies more and the catholyte improved substrate treatability more. The 100-mM anolyte buffer was the best for anode performance; however, the 200-mM catholyte buffer was the best for cathode and RED. This is the first study to comprehensively analyze the effect of electrolyte bicarbonate concentration on MRC system. •Dissolved carbon dioxide is applied to MRC.•High electrolyte buffer concentration have a beneficial effect on MRC performance.•Anolyte buffer became the dominant factor.•The electrolyte buffer concentration affected the RED resistance.
ISSN:2214-7144
2214-7144
DOI:10.1016/j.jwpe.2024.106475