Kyoung-Yeol Kim scite author profile

Different microbial electrochemical technologies are being developed for many diverse applications, including wastewater treatment, biofuel production, water desalination, remote power sources, and biosensors. Current and energy densities will always be limited relative to batteries and chemical fuel cells, but these technologies have other advantages based on the self-sustaining nature of the microorganisms that can donate or accept electrons from an electrode, the range of fuels that can be used, and versatility in the chemicals that can be produced. The high cost of membranes will likely limit applications of microbial electrochemical technologies that might require a membrane. For microbial fuel cells, which do not need a membrane, questions about whether larger-scale systems can produce power densities similar to those obtained in laboratory-scale systems remain. It is shown here that configuration and fuel (pure chemicals in laboratory media vs actual wastewaters) remain the key factors in power production, rather than the scale of the application. Systems must be scaled up through careful consideration of electrode spacing and packing per unit volume of the reactor.

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Methanogenesis control by employing various environmental stress conditions in two-chambered microbial fuel cells

Chae

Choi

Kim

et al. 2010

Bioresource Technology

167

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Electricity from methane by reversing methanogenesis

et al. 2017

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Given our vast methane reserves and the difficulty in transporting methane without substantial leaks, the conversion of methane directly into electricity would be beneficial. Microbial fuel cells harness electrical power from a wide variety of substrates through biological means; however, the greenhouse gas methane has not been used with much success previously as a substrate in microbial fuel cells to generate electrical current. Here we construct a synthetic consortium consisting of: (i) an engineered archaeal strain to produce methyl-coenzyme M reductase from unculturable anaerobic methanotrophs for capturing methane and secreting acetate; (ii) micro-organisms from methane-acclimated sludge (including Paracoccus denitrificans) to facilitate electron transfer by providing electron shuttles (confirmed by replacing the sludge with humic acids), and (iii) Geobacter sulfurreducens to produce electrons from acetate, to create a microbial fuel cell that converts methane directly into significant electrical current. Notably, this methane microbial fuel cell operates at high Coulombic efficiency.

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The impact of new cathode materials relative to baseline performance of microbial fuel cells all with the same architecture and solution chemistry

Yang

Kim

Saikaly

et al. 2017

Energy Environ. Sci.

109

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Impact of electrode configurations on retention time and domestic wastewater treatment efficiency using microbial fuel cells

2015

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Effects of biofouling on ion transport through cation exchange membranes and microbial fuel cell performance

Choi

Chae

Ajayi

et al. 2011

Bioresource Technology

168

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Selective inhibition of methanogens for the improvement of biohydrogen production in microbial electrolysis cells

Chae

Choi

Kim

et al. 2010

International Journal of Hydrogen Energy

149

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Kyoung-Yeol Kim

Effect of different substrates on the performance, bacterial diversity, and bacterial viability in microbial fuel cells

Assessment of Microbial Fuel Cell Configurations and Power Densities

Methanogenesis control by employing various environmental stress conditions in two-chambered microbial fuel cells

Electricity from methane by reversing methanogenesis

The impact of new cathode materials relative to baseline performance of microbial fuel cells all with the same architecture and solution chemistry

Impact of electrode configurations on retention time and domestic wastewater treatment efficiency using microbial fuel cells

Effects of biofouling on ion transport through cation exchange membranes and microbial fuel cell performance

Selective inhibition of methanogens for the improvement of biohydrogen production in microbial electrolysis cells

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