AI Article Synopsis
- The global energy crisis has led to the advancement of green energy technologies like microbial fuel cells (MFCs), which can treat wastewater while generating bioenergy.
- Factors influencing energy production in MFCs include design types, operational parameters, and the importance of electron transfer mechanisms, all of which are essential for optimizing efficiency.
- Despite challenges in power generation and system scaling, the review highlights various techniques for MFC applications to improve practical use and support environmental science research.
Article Abstract
The global energy crisis has stimulated the development of various forms of green energy technology such as microbial fuel cells (MFCs) that can be applied synergistically and simultaneously toward wastewater treatment and bioenergy generation. This is because electricigens in wastewater can act as catalysts for destroying organic pollutants to produce bioelectricity through bacterial metabolism. In this review, the factors affecting energy production are discussed to help optimize MFC processes with respect to design (e.g., single, double, stacked, up-flow, sediment, photosynthetic, and microbial electrolysis cells) and operational conditions/parameters (e.g., cell potential, microorganisms, substrate (in wastewater), pH, temperature, salinity, external resistance, and shear stress). The significance of electron transfer mechanisms and microbial metabolism is also described to pursue the maximum generation of power by MFCs. Technically, the generation of power by MFCs is still a significant challenge for real-world applications due to the difficulties in balancing between harvesting efficiency and upscaling of the system. This review summarizes various techniques used for MFC-based energy harvesting systems. This study aims to help narrow such gaps in their practical applications. Further, it is also expected to give insights into the upscaling of MFC technology while assisting environmental scientists to gain a better understanding on this energy harvesting approach.
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| http://dx.doi.org/10.1016/j.chemosphere.2021.130828 | DOI Listing |
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