Enhancement of methane production in anaerobic digestion process: A review

[Display omitted] •Recent advances in increasing hydrolysis are introduced.•Strategies for enhancing enzyme activity relevant with VFA generation are reviewed.•Acceleration of direct interspecies electron transfer facilitates methanogenesis.•Improving methane production through special pathway is be...

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Published in	Applied energy Vol. 240; pp. 120 - 137
Main Authors	Li, Yue, Chen, Yinguang, Wu, Jiang
Format	Journal Article
Language	English
Published	Elsevier Ltd 15.04.2019
Subjects	Acidification Anaerobic digestion bioenergy carbon dioxide electron transfer energy enzyme activity enzymes Hydrolysis Interspecies electron transfer Methane methane production Microorganism wastes Methane Hydrolysis Acidification Microorganism Anaerobic digestion Interspecies electron transfer
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Abstract	[Display omitted] •Recent advances in increasing hydrolysis are introduced.•Strategies for enhancing enzyme activity relevant with VFA generation are reviewed.•Acceleration of direct interspecies electron transfer facilitates methanogenesis.•Improving methane production through special pathway is beneficial to anaerobic digestion.•Techno-economic assessment of approaches in the lab-scale is presented. With the increase of energy consumption and wastes generation due to human activities, anaerobic digestion (AD), a technology which turns wastes into bio-energy, is receiving more and more attention in the world. It is well known that there are at least three stages involved in anaerobic digestion, i.e., hydrolysis, acidification, and methanogenesis. Until now, however, the advances in enhancing acidification and methanogenesis have not been reviewed. This review provides a comprehensive overview of the methods reported to enhance each step involved in anaerobic digestion. More important, enzymes are the key to anaerobic digestion, and the strategies for improving enzyme activity are summarized. As electron transfer has been reported to play an important role in anaerobic digestion, the research progress of the approaches for the acceleration of direct interspecies electron transfer in methane production is also introduced. In addition, the recent advances in increasing the reduction of carbon dioxide to methane, which has been widely observed in methanogenesis step, are reviewed. Furthermore, the techno-economic assessment of anaerobic digestion is made, and the key points for future studies are proposed.
AbstractList	With the increase of energy consumption and wastes generation due to human activities, anaerobic digestion (AD), a technology which turns wastes into bio-energy, is receiving more and more attention in the world. It is well known that there are at least three stages involved in anaerobic digestion, i.e., hydrolysis, acidification, and methanogenesis. Until now, however, the advances in enhancing acidification and methanogenesis have not been reviewed. This review provides a comprehensive overview of the methods reported to enhance each step involved in anaerobic digestion. More important, enzymes are the key to anaerobic digestion, and the strategies for improving enzyme activity are summarized. As electron transfer has been reported to play an important role in anaerobic digestion, the research progress of the approaches for the acceleration of direct interspecies electron transfer in methane production is also introduced. In addition, the recent advances in increasing the reduction of carbon dioxide to methane, which has been widely observed in methanogenesis step, are reviewed. Furthermore, the techno-economic assessment of anaerobic digestion is made, and the key points for future studies are proposed. [Display omitted] •Recent advances in increasing hydrolysis are introduced.•Strategies for enhancing enzyme activity relevant with VFA generation are reviewed.•Acceleration of direct interspecies electron transfer facilitates methanogenesis.•Improving methane production through special pathway is beneficial to anaerobic digestion.•Techno-economic assessment of approaches in the lab-scale is presented. With the increase of energy consumption and wastes generation due to human activities, anaerobic digestion (AD), a technology which turns wastes into bio-energy, is receiving more and more attention in the world. It is well known that there are at least three stages involved in anaerobic digestion, i.e., hydrolysis, acidification, and methanogenesis. Until now, however, the advances in enhancing acidification and methanogenesis have not been reviewed. This review provides a comprehensive overview of the methods reported to enhance each step involved in anaerobic digestion. More important, enzymes are the key to anaerobic digestion, and the strategies for improving enzyme activity are summarized. As electron transfer has been reported to play an important role in anaerobic digestion, the research progress of the approaches for the acceleration of direct interspecies electron transfer in methane production is also introduced. In addition, the recent advances in increasing the reduction of carbon dioxide to methane, which has been widely observed in methanogenesis step, are reviewed. Furthermore, the techno-economic assessment of anaerobic digestion is made, and the key points for future studies are proposed.
Author	Chen, Yinguang Wu, Jiang Li, Yue
Author_xml	– sequence: 1 givenname: Yue orcidid: 0000-0002-9298-0338 surname: Li fullname: Li, Yue organization: State Key Laboratory of Pollution Control and Resource Reuse, School of Environmental Science and Engineering, Tongji University, 1239 Siping Road, Shanghai 200092, China – sequence: 2 givenname: Yinguang surname: Chen fullname: Chen, Yinguang email: yinguangchen@tongji.edu.cn organization: State Key Laboratory of Pollution Control and Resource Reuse, School of Environmental Science and Engineering, Tongji University, 1239 Siping Road, Shanghai 200092, China – sequence: 3 givenname: Jiang surname: Wu fullname: Wu, Jiang organization: College of Architecture and Urban Planning, Tongji University, 1239 Siping Road, Shanghai 200092, China
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Snippet	[Display omitted] •Recent advances in increasing hydrolysis are introduced.•Strategies for enhancing enzyme activity relevant with VFA generation are... With the increase of energy consumption and wastes generation due to human activities, anaerobic digestion (AD), a technology which turns wastes into...
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SubjectTerms	Acidification Anaerobic digestion bioenergy carbon dioxide electron transfer energy enzyme activity enzymes Hydrolysis Interspecies electron transfer Methane methane production Microorganism wastes
Title	Enhancement of methane production in anaerobic digestion process: A review
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