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Sustainable Hydrogen Production in Microbial Electrolysis Cells through Activity Control of Electrochemically Active Bacteria
| DC Field | Value | Language |
|---|---|---|
| dc.contributor.advisor | 채규정 | - |
| dc.contributor.author | 박성관 | - |
| dc.date.accessioned | 2022-06-23T08:57:59Z | - |
| dc.date.available | 2022-06-23T08:57:59Z | - |
| dc.date.created | 20220308093429 | - |
| dc.date.issued | 2022 | - |
| dc.identifier.uri | http://repository.kmou.ac.kr/handle/2014.oak/12888 | - |
| dc.identifier.uri | http://kmou.dcollection.net/common/orgView/200000603143 | - |
| dc.description.abstract | A microbial electrolysis cell (MEC) is an environmentally sustainable energy production platform where electrochemically active bacteria (EAB) convert the organic substances in wastewater into hydrogen. MEC is driven by the two major processes: 1) degradation of organic matters into protons (H+), electrons (e-) and carbon dioxide (CO2) in the anode, and followed by 2) reduction of H+ and e- that produces hydrogen gas (H2) in the cathode. Therefore, the sufficient provision of H+ and e- is crucial for fluent H2 production via increasing both the electrobiochemical activity of the anode and the reduction efficiency of the cathode. In this study, the problems of core technology in MEC was identified and solved to increase the efficiency of bioelectrochemical hydrogen production. First, the inefficient use of space in carbon materials based anode, where EABs grow. Carbon-based materials are mainly used in oxidation electrodes due to their high electrical conductivity and porosity, but the hydrophobic nature of carbon-based anodes suppresses the release of the produced gas and water penetration, significantly reducing the possibility of microbial attachment. Therefore, we tried to utilize all areas smoothly through surface improvement. The next problem is the interspecies substrate competition of microorganisms. The anaerobic sludge used for microbial species contains a large amount of methane bacteria as well as EABs, and the electron generated by methane is a loss in terms of hydrogen production. In order to fully use this electrons for hydrogen production, methanogenesis were controlled to reduce methane production and increase hydrogen production. Finally, the reduction of hydrogen ion transfer efficiency due to biofilm formation on the surface of the proton exchange membrane (PEM). When MEC is operated for a long time, microorganisms formated bio-films on the surface of the PEM, a channel where protons are transferred, and these bio-films reduce the efficiency of proton transfer, reducing hydrogen production. Therefore, a synergistic anti-biofouling technology was developed and applied to increase durability of PEM. The development of such core technologies for MEC has enabled economic and efficient hydrogen production, which will contribute to the establishment of a diverse types of larger bioelectrochemical hydrogen production platform in the future. | - |
| dc.description.tableofcontents | Chapter 1. General introduction 1 1.1 Background 2 1.1.1 Microbial fuel cells (MFCs) 3 1.1.2 Microbial electrolysis cells (MECs) 5 1.1.3 Microbial electrosynthesis (MES) 6 1.1.4 Microbial desalination cells (MDCs) 7 1.1.5 Problem statements 8 1.2 Research objectives 9 1.3 References 11 Chapter 2. Literature review 15 2.1 Microbial electrolysis cell: An overview of operation mechanism 16 2.2 Previous studies on factors governing the performance of MECs 17 2.3 Core technology in MEC 22 2.3.1 Anode materials 22 2.3.2 Cathode materials 24 2.3.3 Electrode modification for enhancing the performance of MECs 26 2.4 Previous studies for MEC scale-up 27 2.5 Scale-up Challenges of MECs 29 2.6 References 33 Chapter 3. Maximizing electrochemical microbial activity through an electrobiocompatible anode made by bi-functionalizing surface 56 3.1 Introduction 57 3.2 Experimental 61 3.2.1 Preparation of functionalized anode 61 3.2.2 Characterization of functionalized anodes 64 3.2.3 H2-producing MEC setup and operation 65 3.2.4 Electron transfer and produced gas evaluation 66 3.2.5 Microbial attachment and community analysis depending on depth of anode 67 3.3 Results and discussion 71 3.3.1 Confirmation of the functionalizing anode surface 71 3.3.2 Characterization of the anode 75 3.3.3 Performance of MEC equipped with functionalized anode 82 3.3.4 Microbial dynamics across the anode layers 87 3.4 Conclusion 92 3.5 References 92 Chapter 4. Intensive production of hydrogen and an on-demand strategy through methanogenesis control 100 4.1 Introduction 101 4.2 Experimental 106 4.2.1 Operational conditions of MEC 106 4.2.2 Methanogenesis stimulant and inhibitor 108 4.2.3 Produced gas measurement and analysis 109 4.2.4 Gas production kinetic model 110 4.2.5 Microbial community analysis 111 4.2.6 Quantitative PCR targeting mcrA genes 111 4.3 Results and discussion 112 4.3.1 Stimulation of methane production using CoM injection 112 4.3.2 Microbial community changes with CoM injection 118 4.3.3 Inhibition of methane production using 2-BES 121 4.3.4 Microbial community changes after 2-BES injection 125 4.3.5 Dual-methanogenic pathway 128 4.3.6 Overall energy conversion and efficiency depending on target electrobiofuels 131 4.4 Conclusion 134 4.5 References 136 Chapter 5. Biofouling mitigation on the surface of proton exchange membrane for maintenance of hydrogen production in MEC 145 5.1 Introduction 146 5.2 Experimental 149 5.2.1 Membrane preparation and modification 149 5.2.2 Membrane characterization (8 samples) 152 5.2.3 Evaluation of anti-biofouling effect using MEC after six-month operation (4 samples) 155 5.3 Results and discussion 157 5.3.1 Membrane characterization 157 5.3.2 Long-term performance verification for MEC use 168 5.4 Conclusion 172 5.5 References 173 Chapter 6. Overall conclusion & Further applications 181 Summary in Korean (국문요약) 185 | - |
| dc.language | eng | - |
| dc.publisher | 한국해양대학교 대학원 | - |
| dc.rights | 한국해양대학교 논문은 저작권에 의해 보호받습니다. | - |
| dc.title | Sustainable Hydrogen Production in Microbial Electrolysis Cells through Activity Control of Electrochemically Active Bacteria | - |
| dc.title.alternative | 전기화학적 활성 박테리아의 활성도 조절을 통한 미생물전해전지 내 지속가능한 수소 생산 | - |
| dc.type | Dissertation | - |
| dc.date.awarded | 2022. 2 | - |
| dc.embargo.liftdate | 2023-12-31 | - |
| dc.contributor.alternativeName | Sung-Gwan Park | - |
| dc.contributor.department | 대학원 토목환경공학과 | - |
| dc.contributor.affiliation | 한국해양대학교 대학원 토목환경공학과 | - |
| dc.description.degree | Doctor | - |
| dc.identifier.bibliographicCitation | [1]박성관, “Sustainable Hydrogen Production in Microbial Electrolysis Cells through Activity Control of Electrochemically Active Bacteria,” 한국해양대학교 대학원, 2022. | - |
| dc.subject.keyword | Microbial electrolysis cell | - |
| dc.subject.keyword | Anode material | - |
| dc.subject.keyword | Methanogenesis control | - |
| dc.subject.keyword | Anti-biofouling | - |
| dc.subject.keyword | Hydrogen production | - |
| dc.subject.keyword | Sustainable development | - |
| dc.contributor.specialty | 환경공학 | - |
| dc.identifier.holdings | 000000001979▲200000002763▲200000603143▲ | - |
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