Approaches to polymer electrolyte membrane fuel cells (PEMFCs) and their cost

Renewable and Sustainable Energy Reviews

Volumn 52, Issue , 2015, Pages 897-906

  Guerrero Moreno, Nayibe ^a   Cisneros Molina, Myriam ^b   Gervasio, Dominic ^c   Pérez Robles, Juan Francisco ^a  

^a DEPARTAMENTO DE FÍSICA   (Mexico)

^b Comisin Nacional de Vivienda CONAVI ^*  (Mexico)

^c University of Arizona   (United States)

Author keywords

Bottom up; Cost analysis; DFMA; Fuel cell; MEA; PEMFC

Indexed keywords

CATALYSTS; COST BENEFIT ANALYSIS; COST REDUCTION; INTERNAL COMBUSTION ENGINES; MEMBRANES; POLYELECTROLYTES; SOLID ELECTROLYTES;

AUTOMOTIVE APPLICATIONS; BOTTOM UP; CELL-BE; CELL/B.E; COST ANALYSIS; COST TARGETS; DFMA; LARGE-SCALES; MEA; ]+ CATALYST;

PROTON EXCHANGE MEMBRANE FUEL CELLS (PEMFC);

EID: 84939782651     PISSN: 13640321     EISSN: 18790690     Source Type: Journal    
DOI: 10.1016/j.rser.2015.07.157     Document Type: Review

References (87)

1. Jianlu Zhang, Zhong Xie, Jiujun Zhang, Yanghua Tang, Chaojie Song, Titichai Navessin, and et al. High temperature PEM fuel cells J Power Sources 160 2 2006 872 891
2. Suk-Won Cha, Whitney Colella, and Fritz B. Prinz Fuel cell fundamentals 2006 John Wiley & Sons New York
3. Lee Ji-Yong, Yoo Moosang, Cha Kyounghoon, Lim Tae Won, Hur Tak. Life cycle cost analysis to examine the economical feasibility of hydrogen as an alternative fuel. Int J Hydrogen Energy 2009;34(10):4243-55.
4. S.J. Peighambardoust, S. Rowshanzamir, and M. Amjadi Review of the proton exchange membranes for fuel cell applications Int J Hydrog Energy 35 17 2010 9349 9384
5. Handbook, fuel cell. EG&G technical services. Inc., Albuquerque, NM, DOE/NETL-2004/1206; 2004.
6. Jung-Ho Wee Applications of proton exchange membrane fuel cell systems Renew Sustain Energy Rev 11 2007 1720 1738
7. Amrit Chandan, Mariska Hattenberger, Ahmad El-Kharouf, Shangfeng Du, Aman Dhir, Valerie Self, and et al. High temperature (HT) polymer electrolyte membrane fuel cells (PEMFC) - a review J Power Sources 231 2013 264 278
8. Rayment Chris, Sherwin Scott. Introduction to fuel cell technology, vol. 2. University of Notre Dame; 2003. p. 49-150.
9. 2012 Fuel Cell Technologies Market Report. US Department of Energy. Office of energy and renewable energy fuel cell technologies office; 2013. p. 1-42.
10. 2013 Fuel Cell Technologies Market Report. US Department of Energy. Office of energy and renewable energy fuel cell technologies office; 2014. p. 1-61.
11. Established, Fuel Cells Becoming. The fuel cell industry review 2013. A quarterly journal of research on the science and technology of the platinum group metals and developments in their application in industry, vol. 57, no. 4; 2013. p. 310.
12. Pathways to commercial success: technologies and products supported by the fuel cell technologies office. Prepared by Pacific Northwest National Laboratory for the U.S. Department of Energy Fuel Cell Technologies Office; 2013.
13. Sandra Curtin, Gangi Jennifer, Skukowski Ryan. The business case for fuel cells 2013 reliability, resiliency and savings. Fuel cell 2000; 2013.
14. Cottrell Clint Alex, Grasman Scott E, Thomas Mathew, Martin Kevin Braun, Sheffield John W. Strategies for stationary and portable fuel cell markets. Int J Hydrog Energy 2011;36(13):7969-75.
15. Wang Yun, Chen Ken S, Mishler Jeffrey, Cho Sung Chan, Adroher Xavier Cordobés. A review of polymer electrolyte membrane fuel cells: technology, applications, and needs on fundamental research. Appl Energy 2011;88(4):981-1007.
16. Kocha Shyam S. Polymer electrolyte membrane (PEM) fuel cells, automotive applications. In: Fuel cells. New York: Springer; 2013. p. 473-518.
17. Ma Yan, Karady George G, Winston III Anthony, Gilbert Palomino, Hess Robert, Pelley Don. Economic feasibility prediction of the commercial fuel cells. Energy Convers Manag 2009;50(2):422-30.
18. Yacobucci Brent D, Curtright Aimee E. A hydrogen economy and fuel cells: an overview. In: CRS report for congress; 2004. p. 1-12.
19. Jenn-Jiang Hwang Sustainability study of hydrogen pathways for fuel cell vehicle applications Renew Sustain Energy Rev 19 2013 220 229
20. Shang Jinlei. The role of hydrogen and fuel cells for ultra low carbon vehicles [Ph.D. dissertation]. University of Birmingham; 2014.
21. Aceves Salvador M, Petitpas Guillaume, Espinosa-Loza Francisco, Matthews Manyalibo J, Ledesma-Orozco Elias. Safe, long range, inexpensive and rapidly refuelable hydrogen vehicles with cryogenic pressure vessels. Int J Hydrog Energy 2013;38(5):2480-9.
22. Greene David L, Duleep Gopal. Status and prospects of the global automotive fuel cell industry and plans for deployment of fuel cell vehicles and hydrogen refueling infrastructure. Monograph. Oak Ridge National Laboratory; 2013.
23. Taleb Ali, Kjeang Erik, Maine Elicia. Cost analysis for durable proton exchange membrane in PEM fuel cells. In: Proceedings of PICMET'12 technology management for emerging technologies (PICMET). Sheraton Wall Centre Hotel Vancouver, Canada: IEEE; 2012. p. 2943-50.
24. S. Mekhilef, R. Saidur, and A. Safari Comparative study of different fuel cell technologies Renew Sustain Energy Rev 16 1 2012 981 989
25. Timothy E. Lipman, Jennifer L. Edwards, and Daniel M. Kammen Fuel cell system economics: comparing the costs of generating power with stationary and motor vehicle PEM fuel cell systems Energy Policy 32 1 2004 101 125
26. Haruki Tsuchiya, and Osamu Kobayashi Mass production cost of PEM fuel cell by learning curve Int J Hydrog Energy 29 10 2004 985 990
27. Peter Mock, and Stephan A. Schmid Fuel cells for automotive powertrains - a techno-economic assessment J Power Sources 190 1 2009 133 140
28. Carlson Eric J, Thijssen JHJ. Precious metal availability and cost analysis for PEMFC commercialization. Part IV. F 1; 2003. p. 513-6.
29. Mark Mathias, Hubert Gasteiger, Rohit Makharia, Shyam Kocha, Tim Fuller, Tao Xie, and et al. Can available membranes and catalysts meet automotive polymer electrolyte fuel cell requirements Am Chem Soc Preprints, Div Fuel Chem 49 2 2004 471
30. ACI Technologies, Inc. Manufacturing Fuel Cell Manhattan Project, U.S. Government Contract No. N00014-08-D-0758; November 2011.
31. Satyapal Sunita. Fuel cell cost reduction and R&D progress through the US Department of Energy's Hydrogen Program. Hydrogen Program US Department of Energy. Washington. DC; June 2007.
32. James Brian D, Sandy Thomas CE, Ho Jonathan, Lomax Jr Frank D. F. DFMA cost estimates of fuel-cell/reformer systems at low/medium/high production rates. Progress report for fuel cells for transportation; 2001. p. 44.
33. James B, Ariff G, Kuhn R, Myers D. DFMA cost estimates of fuel-cell/reformer systems at low/medium/high production rates. Report hydrogen, fuel cells, and infrastructure technologies. DOE FY 2003 progress report, Directed Technologies Inc. (DTI); 2003.
34. 2 PEM fuel cell systems for automotive applications: 2008. Update DOE Fuel Cell Technical Publications; 2009.
35. 2 PEM fuel cell systems for automotive applications: 2010 update. Directed technologies inc. report; 2010.
36. 2 PEM fuel cell systems for automotive applications: 2011 update report by strategic analysis, Inc. under Contract No. DE-AC36-08GO28308 for the US Department of Energy; 2011.
37. Spendelow Jacob, Marcinkoski Jason. Fuel cell system cost - 2012. DOE fuel cell technologies program record; 2012.
38. 2 PEM fuel cell systems for transportation applications: 2012 update. Report by strategic analysis, Inc., under Award Number DEEE0005236 for the US Department of Energy, vol. 18; 2012.
39. 2 PEM fuel cell systems for transportation applications: 2013 update. Report by strategic analysis, Inc., under Award Number DE-EE0005236, 2012.
40. Dimitrios Papageorgopoulos, Fuel cells sub-program - session introduction. Annual Merit Review and Peer Evaluation Meeting; 2012.
41. Riahi-Belkaoui Ahmed. The learning curve: a management accounting tool. Quorum Books; 1986.
42. Environmental policy analysis for decision making. Principles of benefit-cost analysis. The economics of non-market goods and resources. vol. 1; 2003. p. 105-40 [Chapter 7].
43. Casey Mary Anne, Donner Jonathan, Kirsch Stuart, Maack Jonathan N. Social analysis: selected tools and techniques. Social Development Department, The World Bank; 2001.
44. Shinya Obara Equipment arrangement planning of a fuel cell energy network optimized for cost minimization Renew Energy 32 3 2007 382 406
45. Frederick W. Lancaster The cost-effectiveness analysis of information retrieval and dissemination systems J Am Soc Inf Sci 22 1 1971 12 27
46. Boothroyd Geoffrey, Dewhurst Peter, Knight Winston A. Product design for manufacture and assembly. Taylor and Francis. 6000 Broken Sound Parkway N.W., Suite 300. Boca Raton, Florida: CRC Press; 2010.
47. Sinha Jayanti, Lasher Stephen, Yang Yong. Direct hydrogen PEMFC manufacturing cost estimation for automotive applications. In: 2009 DOE annual merit review. Washington, DC; 2009.
48. Sinha Jayanti, Lasher Stephen, Yang Yong, Kopf Peter. Direct hydrogen PEMFC manufacturing cost estimation for automotive applications. 2010 DOE annual merit review. Washington, DC; 2010.
49. Carlson EJ, Kopf P, Sinha J, Sriramulu S, Yang Y. Cost analysis of PEM fuel cell. National Renewable Energy Laboratory NREL, systems for transportation, Report No. NREL/SR-560-39104; 2005.
50. Greenberg, Joel S. Economic principles applied to space industry decisions, vol. 201. Aiaa; 2003.
51. C.E. Thomas, Brian D. James, and Franklin D. Lomax Jr Market penetration scenarios for fuel cell vehicles Int J Hydrog Energy 23 10 1998 949 966
52. R.K. Ahluwalia, X. Wang, J. Kwon, A. Rousseau, J. Kalinoski, B. James, and et al. Performance and cost of automotive fuel cell systems with ultra-low platinum loadings J Power Sources 196 10 2011 4619 4630
53. Owen Anthony D, Cockroft Colin. A cost-benefit analysis of Perth's hydrogen fuel cell buses. Report for the minister for planning and infrastructure and for the Western Australian; 2006.
54. K. Jayakumar, S. Pandiyan, N. Rajalakshmi, and K.S. Dhathathreyan Cost-benefit analysis of commercial bipolar plates for PEMFC's J Power Sources 161 1 2006 454 459
55. Ginsberg E, Rinebold J, Aresta P, Drejer T. Fuel cell economic development plan - hydrogen roadmap. Report by The Connecticut Center for advanced technology, Inc.; 2008.
56. Rivera-Tinoco Rodrigo, Schoots Koen, Van Der Zwaan Bob. Learning curves for solid oxide fuel cells. Energy Convers Manag 2012; (57): 86-96.
57. Kreutz Thomas G, Ogden Joan M. Assessment of hydrogen-fueled proton exchange membrane fuel cells for distributed generation and cogeneration. In: Proceedings of the 2000 US DOE hydrogen program review; 2000. p. 1-43.
58. M. Contestabile Analysis of the market for diesel PEM fuel cell auxiliary power units on board long-haul trucks and of its implications for the large-scale adoption of PEMFCs 2009 1 15
59. A. Kazim Economical and environmental assessments of proton exchange membrane fuel cells in public buildings Energy Convers Manag 42 6 2001 763 772
60. Frano Barbir, and Teresa Gomez Efficiency and economics of proton exchange membrane (PEM) fuel cells Int J Hydrog Energy 21 10 1996 891 901
61. Colin J. Cockroft, and Anthony D. Owen The economics of hydrogen fuel cell buses∗ Econ Rec 83 263 2007 359 370
62. I. Staffell, and R.J. Green Estimating future prices for stationary fuel cells with empirically derived experience curves Int J Hydrog Energy 34 14 2009 5617 5628
63. Iain Staffell, and Richard Green The cost of domestic fuel cell micro-CHP systems Int J Hydrog Energy 38 2 2013 1088 1102
64. Zaidi Javaid SM. Polymer membranes for fuel cells, Takeshi Matsuura, editor. 233 Spring Street, New York, NY 10013, USA:Springer; 2009.
65. Jason Marcinkoski, Brian D James, Jeff A Kalinoski, Walt Podolski, Thomas Benjamin, and John Kopasz Manufacturing process assumptions used in fuel cell system cost analyses J Power Sources 196 12 2011 5282 5292
66. Weakley Steven A. Pathways to commercial success: technologies and products supported by the fuel cell technologies program. no. PNNL-21804. Pacific Northwest National Laboratory (PNNL), Richland, WA, US; 2012.
67. Supplies, lower, and recycling expected. Platinum 2012 interim review. A quarterly journal of research on the science and technology of the platinum group metals and developments in their application in industry, vol. 57, no. 1, p. 70-1, 2013
68. Christoph Wannek, Andreas Glüsen, and Detlef Stolten Materials, manufacturing technology and costs of fuel cell membranes Desalination 250 3 2010 1038 1041
69. Yuyan Shao, Geping Yin, Zhenbo Wang, and Yunzhi Gao Proton exchange membrane fuel cell from low temperature to high temperature: material challenges J Power Sources 167 2 2007 235 242
70. Cassidy Houchins, Greg J. Kleen, Jacob S. Spendelow, John Kopasz, David Peterson, Nancy L. Garland, and et al. US DOE progress towards developing low-cost, high performance, durable polymer electrolyte membranes for fuel cell applications Membranes 2 4 2012 855 878
71. Jinfeng Wu, Xiao Zi Yuan, Jonathan J. Martin, Haijiang Wang, Jiujun Zhang, Jun Shen, and et al. A review of PEM fuel cell durability: degradation mechanisms and mitigation strategies J Power Sources 184 1 2008 104 119
72. I. Gatto, A. Stassi, V. Baglio, A. Carbone, E. Passalacqua, A.S. Aricó, and et al. Optimization of perfluorosulphonic ionomer amount in gas diffusion electrodes for PEMFC operation under automotive conditions Electrochim Acta 165 2015 450 455
73. Chenxi Xu, Xiaoteng Liu, Jigui Cheng, and Keith Scott A polybenzimidazole/ionic-liquid-graphite-oxide composite membrane for high temperature polymer electrolyte membrane fuel cells J Power Sources 274 2015 922 927
74. Deuk Ju Kim, Min Jae Jo, and Sang Yong Nam A review of polymer-nanocomposite electrolyte membranes for fuel cell application J Ind Eng Chem 21 2015 36 52
75. Jie Zhang, Shuihua Tang, Longyu Liao, and Weifei Yu Progress in non-platinum catalysts with applications in low temperature fuel cells Chin J Catal 34 6 2013 1051 1065
76. Jeon In-Yup, Choi Hyun-Jung, Choi Min, Seo Jeong-Min, Jung Sun-Min, Kim Min-Jung, et al. Facile, scalable synthesis of edge-halogenated graphene nanoplatelets as efficient metal-free eletrocatalysts for oxygen reduction reaction. Sci Rep 2013;3.
77. Chien-Te Hsieh, Jun-Lun Gu, Yu-Chia Chen, and Dong-Ying Tzou Pulse microwave synthesis of palladium catalysts on graphene electrodes for proton exchange membrane fuel cells Electrochim Acta 98 2013 39 47
78. Ermete Antolini Graphene as a new carbon support for lowerature fuel cell catalysts Appl Catal B: Environ 123 2012 52 68
79. Minmin Liu, Zhang Ruizhong, and Chen Wei Graphene-supported nanoelectrocatalysts for fuel cells: synthesis, properties, and applications Chem Rev 114 10 2014 5117 5160 10.1021/cr400523y
80. Godínez-García Andrés, Francisco Pérez-Robles Juan, Vladimir Martínez-Tejada Hader, and Solorza-Feria Omar Characterization and electrocatalytic properties of sonochemical synthesized PdAg nanoparticles Mater Chem Phys 134 2 2012 1013 1019 10.1016/j.jpowsour.2014.09.17
81. Jiang Rongzhong, Moton Elizabeth, McClure Joshua P, Bowers Zachary. A highly active and alcohol-tolerant cathode electrocatalyst containing Ag nanoparticles supported on graphene. Electrochim Acta 2014;127:146-52.
82. Mróz Waldemar, Budner Bogusaw, Tokarz Wojciech, Piela Piotr, Korwin-Pawlowski Michael L. Ultra-low-loading pulsed-laser-deposited platinum catalyst films for polymer electrolyte membrane fuel cells. J Power Sources 2015;273:885-93.
83. S. Shukla, K. Domican, K. Karan, S. Bhattacharjee, and M. Secanell Analysis of low platinum loading thin polymer electrolyte fuel cell electrodes prepared by inkjet printing Electrochimica Acta 156 2015 289 300 10.1016/j.electacta.2015.01.028
84. Fofana Daouda, Natarajan Sadesh Kumar, Hamelin Jean, Benard Pierre. Low platinum, high limiting current density of the PEMFC (proton exchange membrane fuel cell) based on multilayer cathode catalyst approach. Energy 2014;64:398-403.
85. Koh Joon-Ho, Abbaraju Ravikanth, Parthasarathy Preethy, Virkar Anil V. Design and synthesis of degradation-resistant coreshell catalysts for proton exchange membrane fuel cells. J Power Sources 2014;261:271-7.
86. Fofana Daouda, Natarajan Sadesh Kumar, Hamelin Jean, Benard Pierre. Low platinum, high limiting current density of the PEMFC (proton exchange membrane fuel cell) based on multilayer cathode catalyst approach. Energy 2014;64:398-403.
87. Nabae Yuta, Sonoda Mayu, Yamauchi Chiharu, Hosaka Yo, Isoda Ayano, Aoki Tsutomu. Highly durable Pt-free fuel cell catalysts prepared by multi-step pyrolysis of Fe-phthalocyanine and phenolic resin. Catal Sci Technol 2014;4(5):1400-6.