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[해외논문] A review of the porous transport layer in polymer electrolyte membrane water electrolysis 원문보기

International journal of energy research, v.45 no.10, 2021년, pp.14207 - 14220  

Doan, Tuan Linh (Department of Chemical Engineering Education, Chungnam National University, Daejeon, South Korea) ,  Lee, Han Eol (Graduate School of Energy Science and Technology, Chungnam National University, Daejeon, South Korea) ,  Shah, Syed Shabbar Hassan (Hydrogen Research Department, Korea Institute of Energy Research, Daejeon, South Korea) ,  Kim, MinJoong (Hydrogen Research Department, Korea Institute of Energy Research, Daejeon, South Korea) ,  Kim, Chang‐Hee (Hydrogen Research Department, Korea Institute of Energy Research, Daejeon, South Korea) ,  Cho, Hyun‐Seok (Hydrogen Research Department, Korea Institute of Energy Research, Daejeon, South Korea) ,  Kim, Taekeun (Department of Chemical Engineering Education, Chungnam National University, Daejeon, South Korea)

Abstract AI-Helper 아이콘AI-Helper

SummaryPolymer electrolyte membrane water electrolysis (PEMWE) is the most promising and environmentally friendly method for highly pure hydrogen production when integrated into renewable energy sources. Presently, water electrolysis has merely 4% contribution to global hydrogen production owing to ...

Keyword

#PEMWE   #polymer electrolyte membrane water electrolysis   #porous transport layer   #PTL   #titanium  

참고문헌 (71)

  1. Panwar NL , Kaushik SC , Kothari S . Role of renewable energy sources in environmental protection: A review . Renew Sust Energ Rev . 2011 ; 15 : 1513 ‐ 1524 . http://doi.org/10.1016/j.rser.2010.11.037. 

    상세보기 crossref

  2. Coppez G , Chowdhury S , Chowdhury S . The importance of energy storage in Renewable Power Generation: A review. Page(s) (2010) . 

  3. Khare V , Nema S , Baredar P . Solar–wind hybrid renewable energy system: a review . Renew Sust Energ Rev . 2016 ; 58 : 23 ‐ 33 . 

  4. Jiang Z . Energy development trends and major energy conservation measures . Research on Energy Issues in China , in (ed. Zemin, J. B. T.‐R. on E. I. in C.). Amsterdam : Elservier ; 2009 ; 53 ‐ 87 . https://doi.org/10.1016/B978-0-12-378619-7.00003-8. 

    crossref

  5. OHTA T. Chapter 10: Direct solar energy conversion at sea. Solar‐Hydrogen Energy Systems , in (ed. OHTA T). Oxford: Pergamon Press; 1979 ; 225 ‐ 248 . https://doi.org/10.1016/B978-0-08-022713-9.50016-1. 

    crossref

  6. Kumar H , Bharti B , Aslam S , et al. Structural tailoring of molybdenum disulfide by argon plasma for efficient electrocatalysis performance . Int J Energy Res . 2020 ; 44 : 7846 ‐ 7854 . 

    상세보기

  7. Rosen MA , Koohi‐Fayegh S . The prospects for hydrogen as an energy carrier: an overview of hydrogen energy and hydrogen energy systems . Energy Ecol Environ . 2016 ; 1 : 10 ‐ 29 . 

    상세보기

  8. Kumar H , Wang K , Tang F , Zeng X , Gan L , Su Y . Unveiling active sites by structural tailoring of two‐dimensional niobium disulfide for improved electrocatalytic hydrogen evolution reaction . Int J Energy Res . 2020 ; 44 : 10551 ‐ 10561 . http://doi.org/10.1002/er.5691. 

    상세보기 crossref

  9. Barbir F . Chapter 4: Main cell components, material properties, and processes. PEM Fuel Cells (Second Edition) . Cambridge: Academic Press; 2013 ;73‐117. https://doi.org/10.1016/B978-0-12-387710-9.00004-7. 

    crossref

  10. Omrani R , Shabani B . Gas diffusion layer modifications and treatments for improving the performance of proton exchange membrane fuel cells and electrolysers: a review . Int J Hydrog Energy . 2017 ; 42 : 28515‐28536 . 

    상세보기

  11. Park J , Oh H , Ha T , Lee YI , Min K . A review of the gas diffusion layer in proton exchange membrane fuel cells: durability and degradation . Appl Energy . 2015 ; 155 : 866 ‐ 880 . 

    상세보기

  12. Lee JK , Lee CH , Bazylak A . Pore network modelling to enhance liquid water transport through porous transport layers for polymer electrolyte membrane electrolyzers . J Power Sources . 2019 ; 437 : 226910 . 

    상세보기

  13. Escribano S , Blachot JF , Ethève J , Morin A , Mosdale R . Characterization of PEMFCs gas diffusion layers properties . J Power Sources . 2006 ; 156 : 8 ‐ 13 . 

    상세보기

  14. Ge J , Higier A , Liu H . Effect of gas diffusion layer compression on PEM fuel cell performance . J Power Sources . 2006 ; 159 : 922 ‐ 927 . 

    상세보기

  15. Lee WK , Ho CH , Van Zee JW , Murthy M . Effects of compression and gas diffusion layers on the performance of a PEM fuel cell . J Power Sources . 1999 ; 84 : 45 ‐ 51 . 

  16. Mishra V , Yang F , Pitchumani R . Measurement and prediction of electrical contact resistance between gas diffusion layers and bipolar plate for applications to PEM fuel cells . J Fuel Cell Sci Technol . 2004 ; 1 : 2 ‐ 9 . 

  17. Nitta I , Hottinen T , Himanen O , Mikkola M . Inhomogeneous compression of PEMFC gas diffusion layer. Part I experimental . J Power Sources . 2007 ; 171 : 26 ‐ 36 . 

    상세보기

  18. John Felix Kumar R , Radhakrishnan V , Haridoss P . Enhanced mechanical and electrochemical durability of multistage PTFE treated gas diffusion layers for proton exchange membrane fuel cells . Int J Hydrog Energy . 2012 ; 37 : 10830‐10835 . 

    상세보기

  19. Song S , Zhang H , Ma X , Shao ZG , Zhang Y , Yi B . Bifunctional oxygen electrode with corrosion‐resistive gas diffusion layer for unitized regenerative fuel cell . Electrochem Commun . 2006 ; 8 : 399 ‐ 405 . http://doi.org/10.1016/j.elecom.2006.01.001. 

    상세보기 crossref

  20. Wilde PM , Mändle M , Murata M , Berg N . Structural and physical properties of GDL and GDL/BPP combinations and their influence on PEMFC performance . Fuel Cells . 2004 ; 4 : 180 ‐ 184 . 

    상세보기

  21. Kim T , Popov BN . Development of highly‐active and stable Pt/C catalyst for polymer electrolyte membrane fuel cells under simulated start‐up/shut‐down cycling . Int J Hydrog Energy . 2016 ; 41 : 1828 ‐ 1836 . 

    상세보기

  22. Borisov GR , Stoyanova AE , Lefterova ED , Slavcheva ЕP . A novel non‐carbon gas diffusion layer for PEM water electrolysis anodes . Bulg Chem Commun . 2013 ; 45 : 186 ‐ 190 . 

  23. Bessarabov D , Wang H , Li H , Zhao N . Chapter 11: degradation processes and failure mechanisms in PEM water electrolyzers . PEM Electrolysis for Hydrogen Production, Principles and Applications . Boca Raton : Taylor & Francis Group, LLC ; 2016 . https://doi.org/10.1201/b19096. 

    crossref

  24. Mayyas A Ruth M , Pivovar B , Bender G , Wipke K . Manufacturing cost analysis for proton exchange membrane water electrolyzers. Natl. Renew. Energy Lab. 65 ( 2019 ). 

  25. Mo J , Steen SM , Zhang FY , Toops TJ , Brady MP , Green JB . Electrochemical investigation of stainless steel corrosion in a proton exchange membrane electrolyzer cell . Int J Hydrog Energy . 2015 ; 40 : 12506 ‐ 12511 . http://doi.org/10.1016/j.ijhydene.2015.07.061. 

    상세보기 crossref

  26. Zhang FY , Advani SG , Prasad AK . Performance of a metallic gas diffusion layer for PEM fuel cells . J Power Sources . 2008 ; 176 : 293 ‐ 298 . http://doi.org/10.1016/j.jpowsour.2007.10.055. 

    상세보기 crossref

  27. Zhang FY , Prasad AK , Advani SG . Investigation of a copper etching technique to fabricate metallic gas diffusion media . J Micromech Microeng . 2006 ; 16 : N23 ‐ N27 . http://doi.org/10.1088/0960-1317/16/11/n02. 

    상세보기 crossref

  28. Liu C , Carmo M , Bender G , et al. Performance enhancement of PEM electrolyzers through iridium‐coated titanium porous transport layers . Electrochem Commun . 2018 ; 97 : 96 ‐ 99 . 

    상세보기

  29. Borgardt E , Panchenko O , Hackemüller FJ , et al. Mechanical characterization and durability of sintered porous transport layers for polymer electrolyte membrane electrolysis . J Power Sources . 2018 ; 374 : 84 ‐ 91 . 

    상세보기

  30. Panchenko O , Borgardt E , Zwaygardt W, et al. In‐situ two‐phase flow investigation of different porous transport layer for a polymer electrolyte membrane (PEM) electrolyzer with neutron spectroscopy . J Power Sources . 2018 ; 390 : 108 ‐ 115 . 

    상세보기

  31. Mo J , Dehoff RR , Peter WH , Toops TJ , Green JB , Zhang FY . Additive manufacturing of liquid/gas diffusion layers for low‐cost and high‐efficiency hydrogen production . Int J Hydrog Energy . 2016 ; 41 : 3128 ‐ 3135 . http://doi.org/10.1016/j.ijhydene.2015.12.111. 

    상세보기 crossref

  32. Chen G , Zhang H , Zhong H , Ma H . Gas diffusion layer with titanium carbide for a unitized regenerative fuel cell . Electrochim Acta . 2010 ; 55 : 8801 ‐ 8807 . 

    상세보기

  33. Hwang CM , Ishida M , Ito H , et al. Influence of properties of gas diffusion layers on the performance of polymer electrolyte‐based unitized reversible fuel cells . Int J Hydrog Energy . 2011 ; 36 : 1740 ‐ 1753 . 

    상세보기

  34. Lee CH, Banerjee R, Arbabi F, Hinebaugh J, Bazylak A. Porous transport layer related mass transport losses in polymer electrolyte membrane electrolysis: A review . ASME 2016 14th International Conference on Nanochannels, Microchannels, and Minichannels collocated with the ASME 2016 Heat Transfer Summer Conference and the ASME 2016 Fluids Engineering Division Summer Meeting . 2017;1:1‐7. 

  35. Lopata J , Kang Z , Young J , Bender G , Weidner JW , Shimpalee S . Effects of the transport/catalyst layer interface and catalyst loading on mass and charge transport phenomena in polymer electrolyte membrane water electrolysis devices . J Electrochem Soc . 2020 ; 167 : 064507 . http://doi.org/10.1149/1945-7111/ab7f87. 

    상세보기 crossref

  36. Grigoriev SA , Millet P , Volobuev SA , Fateev VN . Optimization of porous current collectors for PEM water electrolysers . Int J Hydrog Energy . 2009 ; 34 : 4968 ‐ 4973 . 

    상세보기

  37. Li H , Fujigaya T , Nakajima H , Inada A , Ito K . Optimum structural properties for an anode current collector used in a polymer electrolyte membrane water electrolyzer operated at the boiling point of water . J Power Sources . 2016 ; 332 : 16 ‐ 23 . 

    상세보기

  38. Kang Z , Yang G , Mo J, et al. Novel thin/tunable gas diffusion electrodes with ultra‐low catalyst loading for hydrogen evolution reactions in proton exchange membrane electrolyzer cells . Nano Energy . 2018 ; 47 : 434 ‐ 441 . 

    상세보기

  39. Lettenmeier P , Kolb S , Sata N, et al. Comprehensive investigation of novel pore‐graded gas diffusion layers for high‐performance and cost‐effective proton exchange membrane electrolyzers . Energy Environ Sci . 2017 ; 10 : 2521 ‐ 2533 . 

    상세보기

  40. Omrani R , Shabani B . Review of gas diffusion layer for proton exchange membrane‐based technologies with a focus on unitised regenerative fuel cells . Int J Hydrog Energy . 2019 ; 44 : 3834 ‐ 3860 . 

    상세보기

  41. Ito H , Abe K , Ishida M , Hwang CM , Nakano A . Effect of through‐plane polytetrafluoroethylene distribution in a gas diffusion layer on a polymer electrolyte unitized reversible fuel cell . Int J Hydrog Energy . 2015 ; 40 : 16556‐16565 . 

    상세보기

  42. Nouri‐Khorasani A , Tabu Ojong E , Smolinka T , Wilkinson DP . Model of oxygen bubbles and performance impact in the porous transport layer of PEM water electrolysis cells . Int J Hydrog Energy . 2017 ; 42 : 28665‐28680 . 

    상세보기

  43. Ito H , Maeda T , Nakano A, et al. Experimental study on porous current collectors of PEM electrolyzers . Int J Hydrog Energy . 2012 ; 37 : 7418 ‐ 7428 . 

    상세보기

  44. Majasan JO , Iacoviello F , Shearing PR , Brett DJL . Effect of microstructure of porous transport layer on performance in polymer electrolyte membrane water electrolyser . Energy Procedia . 2018 ; 151 : 111 ‐ 119 . 

    상세보기

  45. Zhan Z , Xiao J , Li D , Pan M , Yuan R . Effects of porosity distribution variation on the liquid water flux through gas diffusion layers of PEM fuel cells . J Power Sources . 2006 ; 160 : 1041 ‐ 1048 . 

    상세보기

  46. Huang YX , Cheng CH , Wang XD , Jang JY . Effects of porosity gradient in gas diffusion layers on performance of proton exchange membrane fuel cells . Energy . 2010 ; 35 : 4786 ‐ 4794 . 

  47. Zhang Y , Verma A , Pitchumani R . Optimum design of polymer electrolyte membrane fuel cell with graded porosity gas diffusion layer . Int J Hydrog Energy . 2016 ; 41 : 8412 ‐ 8426 . 

    상세보기

  48. Zhan Z , Xiao J , Zhang Y , Pan M , Yuan R . Gas diffusion through differently structured gas diffusion layers of PEM fuel cells . Int J Hydrog Energy . 2007 ; 32 : 4443 ‐ 4451 . 

    상세보기

  49. Hussain N , Van Steen E , Tanaka S , Levecque P . Metal based gas diffusion layers for enhanced fuel cell performance at high current densities . J Power Sources . 2017 ; 337 : 18 ‐ 24 . 

    상세보기

  50. Steen SM , Mo J , Kang Z , Yang G , Zhang FY . Investigation of titanium liquid/gas diffusion layers in proton exchange membrane electrolyzer cells . Int J Green Energy . 2017 ; 14 : 162 ‐ 170 . 

  51. Mo J , Steen S , Han B , et al. Investigation of titanium felt transport parameters for energy storage and hydrogen/oxygen production. Paper presented at: 13th Int. Energy Convers. Eng. Conf . ( 2015 ). https://doi.org/10.2514/6.2015-3914. 

    crossref

  52. Mo J , Kang Z , Yang G, et al. Thin liquid/gas diffusion layers for high‐efficiency hydrogen production from water splitting . Appl Energy . 2016 ; 177 : 817 ‐ 822 . 

    상세보기

  53. Siracusano S , Di Blasi A , Baglio V, et al. Optimization of components and assembling in a PEM electrolyzer stack . Int J Hydrog Energy . 2011 ; 36 : 3333 ‐ 3339 . 

    상세보기

  54. Suermann M , Takanohashi K , Lamibrac A , Schmidt TJ , Büchi FN . Influence of operating conditions and material properties on the mass transport losses of polymer electrolyte water electrolysis . J Electrochem Soc . 2017 ; 164 : F973 ‐ F980 . 

    상세보기

  55. Schuler T , Schmidt TJ , Büchi FN . Polymer electrolyte water electrolysis: correlating performance and porous transport layer structure: part II. Electrochemical performance analysis . J Electrochem Soc . 2019 ; 166 : F555 ‐ F565 . 

    상세보기

  56. Schuler T , Ciccone JM , Krentscher B, et al. Hierarchically structured porous transport layers for polymer electrolyte water electrolysis . Adv Energy Mater . 2020 ; 10 : 1 ‐ 12 . 

  57. Jung HY , Huang SY , Popov BN . High‐durability titanium bipolar plate modified by electrochemical deposition of platinum for unitized regenerative fuel cell (URFC) . J Power Sources . 2010 ; 195 : 1950 ‐ 1956 . 

    상세보기

  58. Jung HY , Huang SY , Ganesan P , Popov BN . Performance of gold‐coated titanium bipolar plates in unitized regenerative fuel cell operation . J Power Sources . 2009 ; 194 : 972 ‐ 975 . 

    상세보기

  59. Lettenmeier P , Kolb S , Burggraf F , Gago AS , Friedrich KA . Towards developing a backing layer for proton exchange membrane electrolyzers . J Power Sources . 2016 ; 311 : 153 ‐ 158 . 

    상세보기

  60. Gago AS , Ansar SA , Saruhan B, et al. Protective coatings on stainless steel bipolar plates for proton exchange membrane (PEM) electrolysers . J Power Sources . 2016 ; 307 : 815 ‐ 825 . 

    상세보기

  61. Hwang CM , Ishida M , Ito H, et al. Effect of titanium powder loading in gas diffusion layer of a polymer electrolyte unitized reversible fuel cell . J Power Sources . 2012 ; 202 : 108 ‐ 113 . 

    상세보기

  62. Feng Q , Yuan XZ , Liu G, et al. A review of proton exchange membrane water electrolysis on degradation mechanisms and mitigation strategies . J Power Sources . 2017 ; 366 : 33 ‐ 55 . 

    상세보기

  63. Rakousky C , Reimer U , Wippermann K , Carmo M , Lueke W , Stolten D . An analysis of degradation phenomena in polymer electrolyte membrane water electrolysis . Int J Hydrog Energy . 2016 ; 326 : 120 ‐ 128 . http://doi.org/10.1016/j.jpowsour.2016.06.082. 

    상세보기 crossref

  64. Weiß A , Siebel A , Bernt M , Shen TH , Tileli V , Gasteiger HA . Impact of intermittent operation on lifetime and performance of a PEM water electrolyzer . J Electrochem Soc . 2019 ; 166 : F487 ‐ F497 . http://doi.org/10.1149/2.0421908jes. 

    상세보기 crossref

  65. Kuttanikkad SP , Prat M , Pauchet J . Pore‐network simulations of two‐phase flow in a thin porous layer of mixed wettability: application to water transport in gas diffusion layers of proton exchange membrane fuel cells . J Power Sources . 2011 ; 196 : 1145 ‐ 1155 . 

    상세보기

  66. Chapuis O , Prat M , Quintard M , Chane‐Kane E , Guillot O , Mayer N . Two‐phase flow and evaporation in model fibrous media . J Power Sources . 2008 ; 178 : 258 ‐ 268 . http://doi.org/10.1016/j.jpowsour.2007.12.011. 

    상세보기 crossref

  67. Lee KJ , Nam JH , Kim CJ . Pore‐network analysis of two‐phase water transport in gas diffusion layers of polymer electrolyte membrane fuel cells . Electrochim Acta . 2009 ; 54 : 1166 ‐ 1176 . 

    상세보기

  68. Gostick JT , Ioannidis MA , Fowler MW , Pritzker MD . Pore network modeling of fibrous gas diffusion layers for polymer electrolyte membrane fuel cells . J Power Sources . 2007 ; 173 : 277 ‐ 290 . 

    상세보기

  69. Luo G , Ji Y , Wang CY , Sinha PK . Modeling liquid water transport in gas diffusion layers by topologically equivalent pore network . Electrochim Acta . 2010 ; 55 : 5332 ‐ 5341 . 

    상세보기

  70. Lee KJ , Nam JH , Kim CJ . Steady saturation distribution in hydrophobic gas‐diffusion layers of polymer electrolyte membrane fuel cells: a pore‐network study . J Power Sources . 2010 ; 195 : 130 ‐ 141 . 

    상세보기

  71. Arbabi F , Kalantarian A , Abouatallah R , Wang R , Wallace JS , Bazylak A . Feasibility study of using microfluidic platforms for visualizing bubble flows in electrolyzer gas diffusion layers . J Power Sources . 2014 ; 258 : 142 ‐ 149 . http://doi.org/10.1016/j.jpowsour.2014.02.042. 

    상세보기 crossref
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