Hydrogen and Methane Generation from Biowaste: Enhancement and Upgrading via Bioelectrochemical Systems

Bo Wang; Wenzong Liu; Cristiano Varrone; Aijie Wang

doi:10.1007/978-981-15-6868-8_5

Hydrogen and Methane Generation from Biowaste: Enhancement and Upgrading via Bioelectrochemical Systems

Bo Wang, Wenzong Liu^*, Cristiano Varrone^*, Aijie Wang

^*Corresponding author for this work

Research output: Contribution to book/anthology/report/proceeding › Book chapter › Research › peer-review

3 Citations (Scopus)

Abstract

Bioelectrochemical systems (BESs) are emerging technologies that are based on catalyzing (bio-)anode and (bio-)cathode reactions from waste biomass by exoelectrogenic microorganisms. Microbial electrolysis cell (MEC), which is one of the BESs’ technologies, is typically used to degrade organic wastes or wastewater for bioenergy recovery and biosynthesis. As one of the promising biotechnologies for resource recovery, value-added products have been obtained by MEC- or ME-integrated systems, such as hydrogen, methane, ethanol, etc. The fundamental reactions of (bio-)electron transport through anodic oxidation are well understood and allow us to increase reactor performance and efficiency. More attentions have been recently paid to cathode reactions on proton/electron transport and recovery, with or without microbial activities. Biogas upgrading systems have also been promoted in integrated systems, by combining bioelectrochemistry with various anaerobic processes. This chapter will focus on energy gas generation from waste organics involved in bioelectrochemical pathways and give an overview of bottlenecks and challenges related to this technology.

Original language	English
Title of host publication	Bioelectrochemical Systems : Vol.2 Current and Emerging Applications
Editors	Prasun Kumar, Chandrasekhar Kuppam
Number of pages	48
Volume	2
Publisher	Springer Nature
Publication date	1 Jan 2021
Pages	88-130
Chapter	5
ISBN (Print)	978-981-15-6867-1
ISBN (Electronic)	978-981-15-6868-8
DOIs	https://doi.org/10.1007/978-981-15-6868-8_5
Publication status	Published - 1 Jan 2021
Externally published	Yes

Keywords

Bioelectrochemical systems
Microbial electrolysis cell
Hydrogen
Methane
Biowaste

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10.1007/978-981-15-6868-8_5

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abstract = "Bioelectrochemical systems (BESs) are emerging technologies that are based on catalyzing (bio-)anode and (bio-)cathode reactions from waste biomass by exoelectrogenic microorganisms. Microbial electrolysis cell (MEC), which is one of the BESs{\textquoteright} technologies, is typically used to degrade organic wastes or wastewater for bioenergy recovery and biosynthesis. As one of the promising biotechnologies for resource recovery, value-added products have been obtained by MEC- or ME-integrated systems, such as hydrogen, methane, ethanol, etc. The fundamental reactions of (bio-)electron transport through anodic oxidation are well understood and allow us to increase reactor performance and efficiency. More attentions have been recently paid to cathode reactions on proton/electron transport and recovery, with or without microbial activities. Biogas upgrading systems have also been promoted in integrated systems, by combining bioelectrochemistry with various anaerobic processes. This chapter will focus on energy gas generation from waste organics involved in bioelectrochemical pathways and give an overview of bottlenecks and challenges related to this technology.",

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Hydrogen and Methane Generation from Biowaste: Enhancement and Upgrading via Bioelectrochemical Systems. / Wang, Bo; Liu, Wenzong; Varrone, Cristiano et al.
Bioelectrochemical Systems: Vol.2 Current and Emerging Applications. ed. / Prasun Kumar; Chandrasekhar Kuppam. Vol. 2 Springer Nature, 2021. p. 88-130.

Research output: Contribution to book/anthology/report/proceeding › Book chapter › Research › peer-review

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AU - Varrone, Cristiano

AU - Wang, Aijie

PY - 2021/1/1

Y1 - 2021/1/1

N2 - Bioelectrochemical systems (BESs) are emerging technologies that are based on catalyzing (bio-)anode and (bio-)cathode reactions from waste biomass by exoelectrogenic microorganisms. Microbial electrolysis cell (MEC), which is one of the BESs’ technologies, is typically used to degrade organic wastes or wastewater for bioenergy recovery and biosynthesis. As one of the promising biotechnologies for resource recovery, value-added products have been obtained by MEC- or ME-integrated systems, such as hydrogen, methane, ethanol, etc. The fundamental reactions of (bio-)electron transport through anodic oxidation are well understood and allow us to increase reactor performance and efficiency. More attentions have been recently paid to cathode reactions on proton/electron transport and recovery, with or without microbial activities. Biogas upgrading systems have also been promoted in integrated systems, by combining bioelectrochemistry with various anaerobic processes. This chapter will focus on energy gas generation from waste organics involved in bioelectrochemical pathways and give an overview of bottlenecks and challenges related to this technology.

AB - Bioelectrochemical systems (BESs) are emerging technologies that are based on catalyzing (bio-)anode and (bio-)cathode reactions from waste biomass by exoelectrogenic microorganisms. Microbial electrolysis cell (MEC), which is one of the BESs’ technologies, is typically used to degrade organic wastes or wastewater for bioenergy recovery and biosynthesis. As one of the promising biotechnologies for resource recovery, value-added products have been obtained by MEC- or ME-integrated systems, such as hydrogen, methane, ethanol, etc. The fundamental reactions of (bio-)electron transport through anodic oxidation are well understood and allow us to increase reactor performance and efficiency. More attentions have been recently paid to cathode reactions on proton/electron transport and recovery, with or without microbial activities. Biogas upgrading systems have also been promoted in integrated systems, by combining bioelectrochemistry with various anaerobic processes. This chapter will focus on energy gas generation from waste organics involved in bioelectrochemical pathways and give an overview of bottlenecks and challenges related to this technology.

KW - Bioelectrochemical systems

KW - Microbial electrolysis cell

KW - Hydrogen

KW - Methane

KW - Biowaste

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ER -

Hydrogen and Methane Generation from Biowaste: Enhancement and Upgrading via Bioelectrochemical Systems

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