Optimizing power generation in sediment microbial fuel cells through multi-electrode configurations

•Novel findings on the impact of anode and cathode configurations on sediment microbial fuel cell performance.•Identification of optimal electrode setups for enhanced power generation in SMFCs.•Demonstration of significant performance improvements through strategic multi-electrode configurations.•In...

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Bibliographic Details
Published in:Journal of the Taiwan Institute of Chemical Engineers 2024-10, p.105809, Article 105809
Main Authors: Abdollahpoor, Hossein Deris, Rahimnejad, Mostafa, Mashkour, Mehrdad, Oh, Sang-Eun, Soavi, Francesca
Format: Article
Language:English
Subjects:
Electricity generation
Graphite electrodes
Multi-electrode systems
Sediment microbial fuel cell
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Summary:•Novel findings on the impact of anode and cathode configurations on sediment microbial fuel cell performance.•Identification of optimal electrode setups for enhanced power generation in SMFCs.•Demonstration of significant performance improvements through strategic multi-electrode configurations.•Insights into the potential for electricity generation enhancement in SMFCs using multi-electrode systems.•Contribution to the advancement of sediment microbial fuel cell technology through experimental testing and analysis. Sediment microbial fuel cells (SMFCs) are efficient platforms for electricity generation and organic/inorganic material removal from sediment. The use of multi-electrode systems is vital for enhancing power and current generation while ensuring stability under bioturbation processes. This study investigates the influence of anode and cathode configurations on the performance of various SMFCs with constant total electrode area and identical sediment. We specifically analyzed the impact of one, two, four, and eight graphite electrodes as anodes and cathodes in four SMFC setups. Cyclic voltammetry (CV) and impedance tests were conducted to assess performance. Results show that the four-anode configuration exhibited increased current generation, while having four cathodes improved performance according to impedance tests. However, using eight cathodes led to decreased power and increased ohmic resistance due to cathodic restriction. SMFC A, with eight anodes and four cathodes, achieved a peak power output of 394 μW, while SMFC B, with four anodes and cathodes, reached a maximum current of 1600 μA. These values represent significant enhancements compared to single-anode setups with the same electrode surface area. This study highlights the potential for improving SMFC performance through strategic multi-electrode configurations.
ISSN:1876-1070
DOI:10.1016/j.jtice.2024.105809