Role of microbial electrosynthesis system in CO2 capture and conversion: a recent advancement toward cathode development

Ibrahim, Irwan; Salehmin, Mohd Nur Ikhmal; Me, Muhammad Farhan Hil; Loh, Kee Shyuan; Jong, Bor Chyan; Lim, Swee Su

doi:10.3389/fmicb.2023.1192187

Cited by 8 publications

(2 citation statements)

References 86 publications

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“…The standardization of testing methods to analyze the performance is anticipated in future studies, which is essential for advancing BES and EET technology and further scale-up. 102 It is considered a potentially sustainable process for transforming electrical energy (produced by renewable sources) into easily storable chemicals under mild environments. 103 In MES, the electroactive microorganisms (called electrotrophs) can utilize electrons (e − ) from external conductors (electrode) as the reducing power for CO 2 conversion.…”

Section: Bess Based On Eet From Electroactive Microorganisms To the E...mentioning

confidence: 99%

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Progress and Prospects for Applications of Extracellular Electron Transport Mechanism in Environmental Biotechnology

Kim,

Baek,

Kim

et al. 2024

ACS EST Eng.

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Extracellular electron transport (EET) is a biological process where microorganisms can donate electrons from the interior of their cells to external electron acceptors or act as electron acceptors to receive electrons from external sources and electrodes. This process often occurs in the surrounding environment or within biofilms, enabling the redox reactions essential for energy metabolism. This review evaluates the latest developments in electron transfer (EET) research in environmental biotechnology, showcasing its varied applications across bioelectrochemical systems (BES), including microbial fuel cells and microbial electrosynthesis for CO 2 upcycling, as well as its utilization in non-BES such as anaerobic digestion and bioleaching for useful resource recovery. The review emphasizes the interdisciplinary approach of EET research, merging microbiology, chemistry, environmental engineering, material science, and system control engineering. This paper provides insights into the performance optimization of EET and the outlook for future industrial and commercial applications. The review also explores the potential applications of EET to mitigate global and environmental challenges, offering innovative biotechnological solutions that pave the way for a sustainable circular bioeconomy.

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Section: Bess Based On Eet From Electroactive Microorganisms To the E...mentioning

confidence: 99%

“…MES is an emerging bioelectrochemical technology for CO 2 sequestration to address climate change . It is considered a potentially sustainable process for transforming electrical energy (produced by renewable sources) into easily storable chemicals under mild environments .…”

Section: Application Of Extracellular Electron Transport In Bioelectr...mentioning

confidence: 99%

Progress and Prospects for Applications of Extracellular Electron Transport Mechanism in Environmental Biotechnology

Kim,

Baek,

Kim

et al. 2024

ACS EST Eng.

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Multi‐Array Tubular Microbial Fuel Cell‐Based Biosensor with Membrane Electrode Assembled Air‐Cathodes

Yeo,

Ang,

Bakar

et al. 2024

Fuel Cells

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Using microbial fuel cells (MFCs) as biosensors ensures a sustainable method for water quality detection. However, the research on MFC‐based biosensors with a tubular setup is still scarce. In this study, a tubular multi‐array MFC‐based biosensor setup with air‐cathodes was assembled under the membrane electrode assembly configuration. Three different materials, including carbon black (CB), Pt/C (PtC), and polyaniline (PANI), were synthesized and coated on the membrane‐facing side of the air‐cathode to demonstrate the effects of modified air‐cathodes on the overall performance of the MFC‐biosensors. Unmodified carbon cloths were used as anodes. Three days of startup period were required by the biosensors before producing an electrical signal output. The highest current density was obtained by the polytetrafluoroethylene (PTFE)/CB/PtC (0.31 A m−2) sample followed by PTFE/CB/PANI (0.09 A m−2), and lastly PTFE/CB (0.05 A m−2). The control (PTFE only) sample did not generate any noticeable electrical signal. The electrochemical impedance spectroscopy analysis showed that the incorporation of PtC on the PTFE/CB sample lowered the charge transfer resistance (Rct), whereas the addition of PANI increased the Rct. Despite the differences in Rct values, both PTFE/CB/PtC and PTFE/CB/PANI samples demonstrated a better current density production than the PTFE/CB sample. Thus, modified air‐cathodes further elevated the biosensor's performance.

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Microbial Electrochemical Technologies: Sustainable Solutions for Addressing Environmental Challenges

Rovira-Alsina,

Romans-Casas,

Perona-Vico

et al. 2024

Advances in Biochemical Engineering/Biotechnology

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Role of microbial electrosynthesis system in CO2 capture and conversion: a recent advancement toward cathode development

Cited by 8 publications

References 86 publications

Progress and Prospects for Applications of Extracellular Electron Transport Mechanism in Environmental Biotechnology

Progress and Prospects for Applications of Extracellular Electron Transport Mechanism in Environmental Biotechnology

Multi‐Array Tubular Microbial Fuel Cell‐Based Biosensor with Membrane Electrode Assembled Air‐Cathodes

Microbial Electrochemical Technologies: Sustainable Solutions for Addressing Environmental Challenges

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