연구동향 분석

Power to Gas 적용을 위한 수전해 전극 제작 및 biogas upgrading 연구 = A Study on Water Electrolysis Electrode Fabrication and Biogas Upgrading Technology for Power to Gas Application

이용호 2022년

논문상세정보
인용/피인용
' Power to Gas 적용을 위한 수전해 전극 제작 및 biogas upgrading 연구 = A Study on Water Electrolysis Electrode Fabrication and Biogas Upgrading Technology for Power to Gas Application' 의 주제별 논문영향력
논문영향력 선정 방법
논문영향력 요약
주제
  • Hydrogenotrophic methanogenesis
  • Power-to-Gas
  • biogasupgrading
  • methanation
  • water electrolysis
동일주제 총논문수 논문피인용 총횟수 주제별 논문영향력의 평균
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' Power to Gas 적용을 위한 수전해 전극 제작 및 biogas upgrading 연구 = A Study on Water Electrolysis Electrode Fabrication and Biogas Upgrading Technology for Power to Gas Application' 의 참고문헌

  • 순천대학교 산학협력단. 산화물 박막 식각 용액 및 이를 이용한 산화 물 박막의 식각 방법, 특허출원 제 10-2010-0121863
    서울: 특허청 [2012]
  • 가부시키가이샤. 구리 에칭액 및 에칭 방법, 특허 출원 제 10-2007-7019781
    가가꾸 미쓰비시 서울: 특허청 [2007]
  • [96] Singer, S. W et al. (2013). “Microbial electrocatalytic (MEC) biofuel production”, In Advanced Biofuels and Bioproducts, Springer, 1091-1099.
    [2013]
  • [91] Brigham, C. J et al. (2011). Bacterial carbon storage to value added products.
    [2011]
  • [87] Brigham, C. J et al. (2013). “Engineering Ralstonia eutropha for production of isobutanol from CO2, H2, and O2”, In Advanced biofuels and bioproducts, Springer, 1065-1090.
    [2013]
  • [82] Lee, S. (2021). “Electroless deposition and patterning for flexible electrodes and its applications”, Ph. D. Thesis, Chung-Ang University, Seoul, Republic of Korea.
  • [81] Lee, D. (2009). “Study on Organic Acid-based Wet Chemical Etching of Doped Zinc Oxide Thin Film”, Master’s Thesis, Hongik University, Seoul, Republic of Korea.
    [2009]
  • [79] Lee, D. (2018). “Study on Dilute HCl-based Cleaning Solution for Metal and Particle Contamination Removal”, Master’s Thesis, Hanyang University, Seoul, Republic of Korea.
    [2018]
  • [60] Kim, Y. (2017). “Electrochemical properties if IPMC actuator with imidazolium ionic liquids”, Master’s Thesis, Konkuk University, Seoul, Republic of Korea.
    [2017]
  • [55] E. S. Kim et al. (2014). NEWS & INFOMATION FOR CHEMICAL ENGINEERS, Vol. 32. No. 1
    [2014]
  • [54] Over, H. (2021). “Fundamental studies of planar single-crystalline oxide model electrodes (RuO2, IrO2) for acidic water splitting”, ACS Catalysis, 11(14), 8848-8871.
  • [51] Lee, J. (2014). “Development of Energy Saving DSA and Electrochemical Sensor for Water Treatment”, Ph. D. Thesis, Seoul National University of Science and Technology, Seoul, Republic of Korea.
    [2014]
  • [50] Bae, J. (2020). “Study on Wet Etching Behavior of Amorphous Metal Electrode for Stretchable Display”, Master’s Thesis, Korea Aerospace University, Goyang, Republic of Korea.
    [2020]
  • [4] Yoo, S. (2021). “Encapsulation of Pt nanocatalyst with N-contaning carbon layer for improving catalytic activity and stability in hydrogen evolution reaction”, Master’s Thesis, Soongsil University, Seoul, Republic of Korea.
  • [49] Kim, J. (2009). “Evolution of Surface Morphology During Wet-Etching of N-type GaN and SiC”, Master’s Thesis, Sunchon National University, Gwangju, Republic of Korea.
    [2009]
  • [48] Yoo, D. (2007). “Study on Wet/Dry Chemical Etching Characterization of Zinc Oxide Film for Transparency Conductive Oxide Application”, Master’s Thesis, Sungkyunkwan University, Seoul, Republic of Korea.
    [2007]
  • [47] Choi, J. (2017). “Electrochemical Study on the Wet Etching Process of PCB Substrate and Panel in Electronic Packaging”, Master’s Thesis, Hongik University, Seoul, Republic of Korea.
    [2017]
  • [46] Kim, H. (2009). “Synthesis and Structural Characterization of Catalyst percursor and Study of Electrochemical Characteristics of Pt, Ru/PEM/Pt MEA for Water Electrolysis”, Master’s Thesis, Myongji University, Seoul, Republic of Korea.
    [2009]
  • [45] Kweon, O. (2007). “Development of Pt/PEM/Pt-Ru MEA Electrode by Chemical Reduction Method for Water Electrolysis”, Master’s Thesis, Myongji Universiry, Seoul, Republic of Korea.
    [2007]
  • [43] Shin, H. (2020). “Prediction of PEM Electrolyser system operating characteristics by applying the analysis of mass transprot phenomena”, Ph. D. Thesis, Chonnam National University, Gwangju, Republic of Korea.
    [2020]
  • [42] Jang, I. (2007). “Preparation and Characteristics of PSf and PEEK Electrolyte Composite Membranes and MEA for Water Electrolysis”, Ph. D. Thesis, Myongji University, Yongin, Republic of Korea.
    [2007]
  • [3] Bae, Y. (2018). “A Study on the effect of the shape of flow channel and electrode in the alkaline water electrolysis stack”, Ph. D. Thesis, Kumoh National Institute of Technology, Gumi, Republic of Korea.
    [2018]
  • [37] Kim, Y. (2018). “Improvements of durability of solid oxide fuel cell through understanding of degradation mechanism and high performance solid oxide electrolytic cells with adcanced cathode materials”, Master’s Thesis, Sejong University, Seoul, Republic of Korea.
    [2018]
  • [34] Kim, J. (2015). “Degradation mechanism of oxygen electrode of Solid Oxide Electrolysis Cells(SOECs)”, Master’s Thesis, Hanyang University, Seoul, Republic of Korea.
    [2015]
  • [2] Bong, S. (2016). “A Study on the electrode and coating electrode using the NiFe2O4 Particle for alkaline water electrolysis”, Master’s Thesis, Hoseo University, Asan, Republic of Korea.
    [2016]
  • [1] Byun, H. (2021). “The Study on the Optimization of CH4 Synthesis through CO2 Hydrogenation in P2G Technology”, Master’s Thesis, The University of Suwon, Suwon, Republic of Korea.
  • [17] White, R. E. (1980). Comprehensive treatise of electrochemistry (Vol. 1, pp. p-143). J. O. M. Bockris, B. E. Conway, & E. Yeager (Eds.). New York: Plenum press.
    [1980]
  • [14] An, D. (2017). “Characteristics of oxygen evolution reaction of Ni-Fe electrodeposition electrode for alkaline water electrolysis”, Master’s Thesis, Chungnam National University, Daejeon, Republic of Korea.
    [2017]
  • [122] Dworkin, M. (2006). “The Prokaryotes: Vol. 7: proteobacteria: delta and epsilon subclasses. Deeply rooting bacteria”, Springer Science & Business Media.
    [2006]
  • [11] Lee, J. (2021). “Cellulose Nanocrystals-Zirconia Nanoparticle Composite Separator with High Ionic Conductivity at Low Electrolyte Contents for Alkaline Electrolyzer”, Master’s Thesis, Chungbuk National University, Cheongju, Republic of Korea.
  • [119] Huber, R et al. (2015). “Methanopyrus”, Bergey's Manual of Systematics of Archaea and Bacteria, 1-4.
    [2015]
  • [115] Garrity, G. M et al. (2001). “Phylum All. Euryarchaeota phy. nov”, In Bergey’s Manual® of Systematic Bacteriology, Springer, 211-355.
    [2001]
  • [113] Boone, D. R et al. (2015). “Methanomicrobiales”, Bergey's Manual of Systematics of Archaea and Bacteria, 1-1.
    [2015]
  • [108] Boone, D. R et al. (1993). “Diversity and taxonomy of methanogens. In Methanogenesis”, Springer, 35-80.
    [1993]
  • [106] Boone, D. R. (2015). Methanobacteria class. nov. Bergey's Manual of Systematics of Archaea and Bacteria, 1-1.
    [2015]
  • [101] Kim, J. (2015). “Development of biological CH4 conversion process using CO2 in flue gas”, Ph. D. Thesis, Seoul National University of Science and Technology, Seoul, Republic of Korea.
    [2015]
  • Use of ionic liquids for π-conjugated polymer electrochemical devices
    Lu , W et al . 297 ( 5583 ) , 983-987 [2002]
  • Transition metal electrocatalysts encapsulated into N-doped carbon nanotubes on reduced graphene oxide nanosheets : efficient water splitting through synergistic effects
    Wan , W et al . 7 ( 25 ) , 15145-15155 [2019]
  • The role of iron in the prevention of nickel electrode deactivation in alkaline electrolysis ”
    Mauer , A et al . 52 ( 11 ) , 3505-3509 . [2007]
  • The path of carbon in photosynthesis
    Calvin , M et al . 107 , 476-480 . [1948]
  • The order methanomicrobiales
    Garcia , J. L et al . 3 , 208-230 . [2006]
  • The order methanobacteriales
    Bonin , A . S et al . 3 , 231-243 . [2006]
  • The intensification technologies to water electrolysis for hydrogen production ? A review
    Wang , M et al . 29 , 573-588 . [2014]
  • The influence of the synthesis method of Ti/RuO2 electrodes on their stability and catalytic activity for electrochemical oxidation of the pesticide carbaryl
    Santos , T. ? . S et al . 148 ( 1-2 ) , 39-47 [2014]
  • The genome sequence of Methanosphaera stadtmanae reveals why this human intestinal archaeon is restricted to methanol and H2 for methane formation and ATP synthesis
    Fricke , W. F et al . 188 ( 2 ) , 642-658 . [2006]
  • The distillation and volatility of ionic liquids
    Earle , M. J et al . 439 ( 7078 ) , 831-834 [2006]
  • The chemical biology of methanogenesis
    Ferry , J. G. 58 ( 14-15 ) , 1775-1783 . [2010]
  • Technology trend in ionic liquids
    Lee , H et al . 16 ( 5 ) , 595-602 . [2005]
  • Taxonomic , phylogenetic , and ecological diversity of methanogenic Archaea
    Garcia , J. L et al . 6 ( 4 ) , 205-226 . [2000]
  • Synthesis and study of a Ce-doped La/Sr titanate for solid oxide fuel cell anode operating directly on methane
    P ? rillat-Merceroz , C et al . 23 ( 6 ) , 1539-1550 . [2011]
  • Study of the oxygen evolution reaction on nickel-based composite coatings in alkaline media
    Kubisztal , J et al . 33 ( 17 ) , 4488-4494 . [2008]
  • Single and coupled electrochemical processes and reactors for the abatement of organic water pollutants : a critical review
    Mart ? nez-Huitle , C et al . 115 ( 24 ) , 13362-13407 . [2015]
  • Role of two 2-oxoglutarate : ferredoxin oxidoreductases in Hydrogenobacter thermophilus under aerobic and anaerobic conditions
    Yamamoto , M et al . 263 ( 2 ) , 189-193 . [2006]
  • Recent development of mixed metal oxide anodes for electrochemical oxidation of organic pollutants in water
    Wu , W et al . 480 , 58-78 [2014]
  • Pulse electrodeposition of nickel selenide nanostructure as a binder-free and high-efficient catalyst for both electrocatalytic hydrogen and oxygen evolution reactions in alkaline solution
    Esmailzadeh , S et al . 334 , 135549 . [2020]
  • Platinum/nickel bicarbonate heterostructures towards accelerated hydrogen evolution under alkaline conditions
    Lao , M et al . 131 ( 16 ) , 5486-5491 . [2019]
  • Physical properties of substituted imidazolium based ionic liquids gel electrolytes
    Sutto , T. E et al . 57 ( 11 ) , 839-846 . [2002]
  • Phylogeny and taxonomy of mesophilic Methanococcus spp . and comparison of rRNA , DNA hybridization , and phenotypic methods
    Keswani , J et al . 46 ( 3 ) , 727-735 . [1996]
  • Photoelectrocatalytic degradation of indanthrene blue dye using Ti/Ru-based electrodes prepared by a modified Pechini method
    Pupo , M et al . 24 , 459-472 . [2013]
  • Oxygen evolution at ultrathin nanostructured Ni ( OH ) 2 layers deposited on conducting glass
    Cibrev , D et al . 38 ( 6 ) , 2746-2753 . [2013]
  • Oxygen evolution and reduction reactions on La0.8Sr0.2CoO3 ( 001 ) , ( 110 ) , and ( 111 ) surfaces in an alkaline solution
    Komo , M et al . 80 ( 10 ) , 834-838 . [2012]
  • Oxide anode derived from Sr-doped LaMnO3 perovskite oxide for SOFCs using LaGaO3 electrolyte
    Ishihara , T et al . 153 ( 11 ) , A2085 . [2006]
  • Optimization of growth media components for polyhydroxyalkanoate ( PHA ) production from organic acids by Ralstonia eutropha
    Yang , Y. H et al . 87 ( 6 ) , 2037-2045 . [2010]
  • Novel FexCr2 ? x ( MoO4 ) 3 electrocatalysts for oxygen evolution reaction
    Singh , R. N et al . 37 ( 20 ) , 15117-15124 . [2012]
  • Non-fermentative pathways for synthesis of branched-chain higher alcohols as biofuels
    Atsumi , S et al . 451 ( 7174 ) , 86-89 . [2008]
  • Nickel based electrocatalysts for oxygen evolution in high current density , alkaline water electrolysers
    Li , X et al . 13 ( 3 ) , 1162-1167 . [2011]
  • New NiFe2 ? xCrxO4 spinel films for O2 evolution in alkaline solutions
    Singh , R. N et al . 51 ( 25 ) , 5515-5523 . [2006]
  • Microbial synthesis of n-butanol , isobutanol , and other higher alcohols from diverse resources
    Lan , E. I et al . 135 , 339-349 . [2013]
  • Methanopyrus kandleri : an archaeal methanogen unrelated to all other known methanogens
    Burggraf , S et al . 14 ( 4 ) , 346-351 . [1991]
  • Methanogenic activity in human periodontal pocket
    Robichaux , M et al . 46 ( 1 ) , 53-58 . [2003]
  • Methanocella paludicola gen. nov. , sp . nov. , a methane-producing archaeon , the first isolate of the lineage ‘ Rice Cluster I ’ , and proposal of the new archaeal order Methanocellales ord . nov
    Sakai , S et al . 58 ( 4 ) , 929-936 . [2008]
  • Metabolic engineering of Clostridium cellulolyticum for production of isobutanol from cellulose
    Higashide , W et al . 77 ( 8 ) , 2727-2733 . [2011]
  • Long-life air working conducting semi-IPN/ionic liquid based actuator
    Vidal , F et al . 142 ( 1-3 ) , 287-291 [2004]
  • List of Bacterial Names with Standing in Nomenclature : a folder available on the Internet
    EUZ ? BY , J. P. ( 47 ( 2 ) , 590-592 . [1997]
  • Lanthanum chromite based catalysts for oxidation of methane directly on SOFC anodes ”
    Sfeir , J et al . 202 ( 2 ) , 229-244 . [2001]
  • Lab-scale alkaline water electrolyzer for bridging material fundamentals with realistic operation
    Ju , W et al . 6 ( 4 ) , 4829-4837 . [2018]
  • Iron molybdates as electrocatalysts for O2 evolution reaction in alkaline solutions
    Singh , R. N et al . 34 ( 11 ) , 4693-4700 . [2009]
  • Ionic liquids in synthesis
    Wasserscheid , P et al . Vol . 1 , p. 367 ) . Weinheim : Wiley-Vch . [2008]
  • Integrated electromicrobial conversion of CO2 to higher alcohols
    Li , H et al . 335 ( 6076 ) , 1596-1596 . [2012]
  • Improving the stability of Sb doped Sn oxides electrode thermally synthesized by using an acid ionic liquid as solvent
    Jara , C. C et al . 171 ( 3 ) , 1253-1262 . [2011]
  • Identification of highly active Fe sites in ( Ni , Fe ) OOH for electrocatalytic water splitting
    Friebel , D et al . 137 ( 3 ) , 1305-1313 [2015]
  • Hydrogen production by water electrolysis/Wasserstoffproduktion durch Elektrolyse von Wasser
    Wendt , H et al . 56 ( 1 ) , 22-28 . [1991]
  • Hydrogen production by alkaline water electrolysis ” , Qu ?
    Santos , D et al . 36 , 1176-1193 [2013]
  • Hierarchical molybdenum phosphide coupled with carbon as a whole pH-range electrocatalyst for hydrogen evolution reaction
    Ge , R et al . 260 , 118196 . [2020]
  • Genome sequence of the bioplastic-producing “ Knallgas ” bacterium Ralstonia eutropha H16
    Pohlmann , A et al . 24 ( 10 ) , 1257-1262 . [2006]
  • Facile synthesis of porous 3D CoNiCu nano-network structure and their activity towards hydrogen evolution reaction
    Wang , C et al . 37 ( 24 ) , 18688-18693 . [2012]
  • Facile synthesis of MoS3/carbon nanotube nanocomposite with high catalytic activity toward hydrogen evolution reaction
    Lin , T et al . 134 , 75-82 [2013]
  • Fabrication of a novel Ti/SnO2 ? Sb ? CeO2 @ TiO2 ? SnO2 electrode and photoelectrocatalytic application in wastewater treatment
    Wang , Y et al . 40 , 744-751 . [2015]
  • Enhanced electrocatalytic activity of trace Pt in ternary CuCoPt alloy nanoparticles for hydrogen evolution
    Lu , W et al . 58 ( 9 ) , 6529-6533 . [2019]
  • Electronic modulation of transition metal phosphide via doping as efficient and pH-universal electrocatalysts for hydrogen evolution reaction
    Xiao , X et al . 9 ( 7 ) , 1970-1975 . [2018]
  • Electrochemistry modeling of proton exchange membrane ( PEM ) water electrolysis for hydrogen production
    Ni , M et al . 16 [2006]
  • Electrochemical properties of imidazolium salt electrolytes for electrochemical capacitor applications
    McEwen , A . B et al . 146 ( 5 ) , 1687 . [1999]
  • Electrochemical degradation of a real textile effluent using boron-doped diamond or β-PbO2 as anode
    Aquino , J. M et al . 192 ( 3 ) , 1275-1282 . [2011]
  • Electrocatalytic properties of new spinel-type MMoO4 ( M= Fe , Co and Ni ) electrodes for oxygen evolution in alkaline solutions
    Singh , R. N et al . 33 ( 16 ) , 4260-4264 . [2008]
  • Efficient solar water splitting , exemplified by RuO2-catalyzed AlGaAs/Si photoelectrolysis
    Licht , S et al . 104 ( 38 ) , 8920-8924 . [2000]
  • Effect of coprecipitated metal ions on the electrochemistry of nickel hydroxide thin films : cyclic voltammetry in 1M KOH
    Corrigan , D. A et al . 136 ( 3 ) , 723 [1989]
  • Ecological aspects of the distribution of different autotrophic CO2 fixation pathways
    Berg , I . A . 77 ( 6 ) , 1925-1936 . [2011]
  • Double-template fabrication of three-dimensional porous nickel electrodes for hydrogen evolution reaction
    Herraiz-Cardona , I et al . 37 ( 3 ) , 2147-2156 . [2012]
  • Development of Ti/ ( RuO2 ) 0.8 ( MO2 ) 0.2 ( M= Ce , Sn or Ir ) anodes for atrazine electro-oxidation . Influence of the synthesis method
    Santos , T. ? et al . 146 , 4-8 . [2015]
  • Decolorization of Methyl Orange Dye at IrO2 ? SnO2 ? Sb2O5 Coated Titanium Anodes ”
    Chaiyont , R et al . 36 ( 1 ) , 123-129 . [2013]
  • Correlation of polar lipid composition with 16S rRNA phylogeny in methanogens . Further analysis of lipid component parts
    Koga , Y et al . 62 ( 2 ) , 230-236 . [1998]
  • Comprehensive investigation on the thermal stability of 66 ionic liquids by thermogravimetric analysis
    Cao , Y et al . 53 ( 20 ) , 8651-8664 . [2014]
  • Compilation of Henry 's law constants ( version 4.0 ) for water as solvent
    Sander , R. 15 ( 8 ) , 4399-4981 . [2015]
  • Characterization of microbial communities in gas industry pipelines
    Zhu , X. Y et al . 69 ( 9 ) , 5354-5363 . [2003]
  • Challenges in the electrochemical modelling of solid oxide fuel and electrolyser cells
    Garc ? a-Camprub ? , M et al . 33 , 701-718 . [2014]
  • Cathode materials for solid oxide fuel cells : a review
    Sun , C et al . 14 ( 7 ) , 1125-1144 . [2010]
  • Biological CO2-methanation : an approach to standardization
    Thema , M et al . 12 ( 9 ) , 1670 . [2019]
  • Beyond the Calvin cycle : autotrophic carbon fixation in the ocean
    H ? gler , M et al . 3 , 261-289 . [2011]
  • Autotrophic carbon fixation in archaea
    Berg , I . A et al . 8 ( 6 ) , 447-460 . [2010]
  • Atomic-scale mechanisms of oxygen electrode delamination in solid oxide electrolyzer cells
    Rashkeev , S. N et al . 37 ( 2 ) , 1280-1291 . [2012]
  • Archaeal phylogeny based on proteins of the transcription and translation machineries : tackling the Methanopyrus kandleri paradox
    Brochier , C et al . 5 ( 3 ) , 1-12 . [2004]
  • Archaeal diversity in waters from deep South African gold mines
    Takai , K. E. N et al . 67 ( 12 ) , 5750-5760 . [2001]
  • Applications of ionic liquids : The state of arts
    Lee , H et al . 21 ( 2 ) , 129-136 . [2010]
  • Anodic evolution of oxygen on ruthenium in acidic solutions
    Iwakura , C et al . 22 ( 4 ) , 329-334 . [1977]
  • An improved stable Ti/Sb ? SnO2 electrode with high performance in electrochemical oxidation processes
    Shao , D et al . 4 ( 41 ) , 21230-21237 . [2014]
  • Alternative pathways of carbon dioxide fixation : insights into the early evolution of life ?
    Fuchs , G. 65 , 631-658 . [2011]
  • Alachlor removal performance of Ti/Ru0.3Ti0.7O2 anodes prepared from ionic liquid solution ”
    de Mello , R et al . 22 ( 5 ) , 1571-1580 . [2018]
  • A mini review of NiFe-based materials as highly active oxygen evolution reaction electrocatalysts
    Gong , M et al . 8 ( 1 ) , 23-39 . [2015]
  • A dicarboxylate/4-hydroxybutyrate autotrophic carbon assimilation cycle in the hyperthermophilic Archaeum Ignicoccus hospitalis
    Huber , H et al . 105 ( 22 ) , 7851-7856 . [2008]
  • A detailed phylogeny for the Methanomicrobiales
    Rouviere , P et al . 15 ( 3 ) , 363-371 . [1992]
  • A Study on the Properties of Anodic Oxide Films formed on Al Alloys in Oxalic Acid
    Jeong , N et al . 53 ( 5 ) , 249-256 . [2020]
  • A 3-hydroxypropionate/4-hydroxybutyrate autotrophic carbon dioxide assimilation pathway in Archaea ”
    Berg , I . A et al . 318 ( 5857 ) , 1782-1786 . [2007]