Emerging bioelectrochemical technologies for biogas production and upgrading in cascading circular bioenergy systems

Emerging bioelectrochemical technologies for biogas production and upgrading in cascading circular bioenergy systems

Summary: Biomethane is suggested as an advanced biofuel for the hard-to-abate sectors such as heavy transport. However, future systems that optimize the resource and production of biomethane have yet to be definitively defined. This paper assesses the opportunity of integrating anaerobic digestion (...

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Main Authors: Xue Ning, Richen Lin, Richard O'Shea, David Wall, Chen Deng, Benteng Wu, Jerry D. Murphy
Format: Article
Language:English
Published: Elsevier 2021-09-01
Series:iScience
Subjects:
Electrochemical energy production
Microbiology
Energy systems
Online Access:http://www.sciencedirect.com/science/article/pii/S2589004221009664
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spelling doaj-ff096c7edd78454793594a15faaff8b42021-09-25T05:10:06ZengElsevieriScience2589-00422021-09-01249102998Emerging bioelectrochemical technologies for biogas production and upgrading in cascading circular bioenergy systemsXue Ning0Richen Lin1Richard O'Shea2David Wall3Chen Deng4Benteng Wu5Jerry D. Murphy6MaREI Centre, Environmental Research Institute, School of Engineering, University College Cork, Cork T23XE10, Ireland; Civil, Structural, and Environmental Engineering, School of Engineering and Architecture, University College Cork, Cork T23XE10, IrelandMaREI Centre, Environmental Research Institute, School of Engineering, University College Cork, Cork T23XE10, Ireland; Civil, Structural, and Environmental Engineering, School of Engineering and Architecture, University College Cork, Cork T23XE10, Ireland; Corresponding authorMaREI Centre, Environmental Research Institute, School of Engineering, University College Cork, Cork T23XE10, Ireland; Civil, Structural, and Environmental Engineering, School of Engineering and Architecture, University College Cork, Cork T23XE10, IrelandMaREI Centre, Environmental Research Institute, School of Engineering, University College Cork, Cork T23XE10, Ireland; Civil, Structural, and Environmental Engineering, School of Engineering and Architecture, University College Cork, Cork T23XE10, IrelandMaREI Centre, Environmental Research Institute, School of Engineering, University College Cork, Cork T23XE10, Ireland; Civil, Structural, and Environmental Engineering, School of Engineering and Architecture, University College Cork, Cork T23XE10, IrelandMaREI Centre, Environmental Research Institute, School of Engineering, University College Cork, Cork T23XE10, Ireland; Civil, Structural, and Environmental Engineering, School of Engineering and Architecture, University College Cork, Cork T23XE10, IrelandMaREI Centre, Environmental Research Institute, School of Engineering, University College Cork, Cork T23XE10, Ireland; Civil, Structural, and Environmental Engineering, School of Engineering and Architecture, University College Cork, Cork T23XE10, IrelandSummary: Biomethane is suggested as an advanced biofuel for the hard-to-abate sectors such as heavy transport. However, future systems that optimize the resource and production of biomethane have yet to be definitively defined. This paper assesses the opportunity of integrating anaerobic digestion (AD) with three emerging bioelectrochemical technologies in a circular cascading bioeconomy, including for power-to-gas AD (P2G-AD), microbial electrolysis cell AD (MEC-AD), and AD microbial electrosynthesis (AD-MES). The mass and energy flow of the three bioelectrochemical systems are compared with the conventional AD amine scrubber system depending on the availability of renewable electricity. An energy balance assessment indicates that P2G-AD, MEC-AD, and AD-MES circular cascading bioelectrochemical systems gain positive energy outputs by using electricity that would have been curtailed or constrained (equivalent to a primary energy factor of zero). This analysis of technological innovation, aids in the design of future cascading circular biosystems to produce sustainable advanced biofuels.http://www.sciencedirect.com/science/article/pii/S2589004221009664Electrochemical energy productionMicrobiologyEnergy systems
collection DOAJ
language English
format Article
sources DOAJ
author Xue Ning
Richen Lin
Richard O'Shea
David Wall
Chen Deng
Benteng Wu
Jerry D. Murphy
spellingShingle Xue Ning
Richen Lin
Richard O'Shea
David Wall
Chen Deng
Benteng Wu
Jerry D. Murphy
Emerging bioelectrochemical technologies for biogas production and upgrading in cascading circular bioenergy systems
iScience
Electrochemical energy production
Microbiology
Energy systems
author_facet Xue Ning
Richen Lin
Richard O'Shea
David Wall
Chen Deng
Benteng Wu
Jerry D. Murphy
author_sort Xue Ning
title Emerging bioelectrochemical technologies for biogas production and upgrading in cascading circular bioenergy systems
title_short Emerging bioelectrochemical technologies for biogas production and upgrading in cascading circular bioenergy systems
title_full Emerging bioelectrochemical technologies for biogas production and upgrading in cascading circular bioenergy systems
title_fullStr Emerging bioelectrochemical technologies for biogas production and upgrading in cascading circular bioenergy systems
title_full_unstemmed Emerging bioelectrochemical technologies for biogas production and upgrading in cascading circular bioenergy systems
title_sort emerging bioelectrochemical technologies for biogas production and upgrading in cascading circular bioenergy systems
publisher Elsevier
series iScience
issn 2589-0042
publishDate 2021-09-01
description Summary: Biomethane is suggested as an advanced biofuel for the hard-to-abate sectors such as heavy transport. However, future systems that optimize the resource and production of biomethane have yet to be definitively defined. This paper assesses the opportunity of integrating anaerobic digestion (AD) with three emerging bioelectrochemical technologies in a circular cascading bioeconomy, including for power-to-gas AD (P2G-AD), microbial electrolysis cell AD (MEC-AD), and AD microbial electrosynthesis (AD-MES). The mass and energy flow of the three bioelectrochemical systems are compared with the conventional AD amine scrubber system depending on the availability of renewable electricity. An energy balance assessment indicates that P2G-AD, MEC-AD, and AD-MES circular cascading bioelectrochemical systems gain positive energy outputs by using electricity that would have been curtailed or constrained (equivalent to a primary energy factor of zero). This analysis of technological innovation, aids in the design of future cascading circular biosystems to produce sustainable advanced biofuels.
topic Electrochemical energy production
Microbiology
Energy systems
url http://www.sciencedirect.com/science/article/pii/S2589004221009664
work_keys_str_mv AT xuening emergingbioelectrochemicaltechnologiesforbiogasproductionandupgradingincascadingcircularbioenergysystems
AT richenlin emergingbioelectrochemicaltechnologiesforbiogasproductionandupgradingincascadingcircularbioenergysystems
AT richardoshea emergingbioelectrochemicaltechnologiesforbiogasproductionandupgradingincascadingcircularbioenergysystems
AT davidwall emergingbioelectrochemicaltechnologiesforbiogasproductionandupgradingincascadingcircularbioenergysystems
AT chendeng emergingbioelectrochemicaltechnologiesforbiogasproductionandupgradingincascadingcircularbioenergysystems
AT bentengwu emergingbioelectrochemicaltechnologiesforbiogasproductionandupgradingincascadingcircularbioenergysystems
AT jerrydmurphy emergingbioelectrochemicaltechnologiesforbiogasproductionandupgradingincascadingcircularbioenergysystems
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