[1] T. Wilberforce, A. Alaswad, A. Palumbo, M. Dassisti, A. Olabi, Advances in stationary and portable fuel cell applications, International Journal of Hydrogen Energy, 41(37) (2016) 16509-16522.
[2] A. Baroutaji, J. Carton, M. Sajjia, A. Olabi, Materials in PEM fuel cells, Reference Module in Materials Science and Materials Engineering, (2016).
[3] E. Alizadeh, M. Barzegari, M. Momenifar, M. Ghadimi, S. Saadat, Investigation of contact pressure distribution over the active area of PEM fuel cell stack, International Journal of Hydrogen Energy, 41(4) (2016) 3062-3071.
[4] M.M. Barzegari, E. Alizadeh, A.H. Pahnabi, Grey-box modeling and model predictive control for cascade-type PEMFC, Energy, (2017).
[5] M. Rahimi-Esbo, A. Ranjbar, A. Ramiar, E. Alizadeh, M. Aghaee, Improving PEM fuel cell performance and effective water removal by using a novel gas flow field, International Journal of Hydrogen Energy, 41(4) (2016) 3023-3037.
[6] F. Barbir, PEM fuel cells: theory and practice, Academic Press, 2012.
[7] E. Alizadeh, S. Rahgoshay, M. Rahimi-Esbo, M. Khorshidian, S. Saadat, A novel cooling flow field design for polymer electrolyte membrane fuel cell stack, International Journal of Hydrogen Energy, 41(20) (2016) 8525-8532.
[8] M.M. Barzegari, M. Dardel, E. Alizadeh, A. Ramiar, Dynamic modeling and validation studies of dead-end cascade H 2/O 2 PEM fuel cell stack with integrated humidifier and separator, Applied Energy, 177 (2016) 298-308.
[9] S. Kang, Quasi-three dimensional dynamic modeling of a proton exchange membrane fuel cell with consideration of two-phase water transport through a gas diffusion layer, Energy, 90, Part 2 (2015) 1388-1400.
[10] V. Mehta, J.S. Cooper, Review and analysis of PEM fuel cell design and manufacturing, Journal of Power Sources, 114(1) (2003) 32-53.
[11] Y.-G. Yoon, W.-Y. Lee, G.-G. Park, T.-H. Yang, C.-S. Kim, Effects of channel configurations of flow field plates on the performance of a PEMFC, Electrochimica Acta, 50(2) (2004) 709-712.
[12] P. Zhou, C. Wu, G. Ma, Contact resistance prediction and structure optimization of bipolar plates, Journal of Power Sources, 159(2) (2006) 1115-1122.
[13] A. Hermann, T. Chaudhuri, P. Spagnol, Bipolar plates for PEM fuel cells: a review, International journal of hydrogen Energy, 30(12) (2005) 1297-1302.
[14] X. Li, I. Sabir, Review of bipolar plates in PEM fuel cells: Flow-field designs, International journal of hydrogen energy, 30(4) (2005) 359-371.
[15] R. Taherian, A review of composite and metallic bipolar plates in proton exchange membrane fuel cell: Materials, fabrication, and material selection, Journal of Power Sources, 265 (2014) 370-390.
[16] A.E. Fetohi, R.A. Hameed, K. El–Khatib, E.R. Souaya, Study of different aluminum alloy substrates coated with Ni–Co–P as metallic bipolar plates for PEM fuel cell applications, international journal of hydrogen energy, 37(14) (2012) 10807-10817.
[17] D.J. Brett, N.P. Brandon, Review of materials and characterization methods for polymer electrolyte fuel cell flow-field plates, Journal of fuel cell science and technology, 4(1) (2007) 29-44.
[18] R.A. Antunes, M.C.L. Oliveira, G. Ett, V. Ett, Corrosion of metal bipolar plates for PEM fuel cells: a review, International Journal of Hydrogen Energy, 35(8) (2010) 3632-3647.
[19] S.-W. Choi, S.H. Park, H.-S. Jeong, J. Cho, S. Park, M.Y. Ha, Improvement of formability for fabricating thin continuously corrugated structures in sheet metal forming process, Journal of mechanical science and technology, 26(8) (2012) 2397-2403.
[20] Q. Hu, D. Zhang, H. Fu, K. Huang, Investigation of stamping process of metallic bipolar plates in PEM fuel cell—Numerical simulation and experiments, International Journal of Hydrogen Energy, 39(25) (2014) 13770-13776.
[21] M. Elyasi, F.A. Khatir, M. Hosseinzadeh, Manufacturing metallic bipolar plate fuel cells through rubber pad forming process, The International Journal of Advanced Manufacturing Technology, (2016) 1-13.
[22] M. Elyasi, F.A. Khatir, M. Hosseinzadeh, Investigation of Die Clearance in Rubber Pad Forming of Metallic Bipolar Plates, Amirkabir Journal of Mechanical Engineering, (2016).
[23] M. Elyasi, H.T. Ghadikolaee, M. Hosseinzadeh, Fabrication of metallic bipolar plates in PEM fuel cell using semi-stamp rubber forming process, The International Journal of Advanced Manufacturing Technology, (2017) 1-12.
[24] O.M. Belali, S.J. Hosseinipour, J.M. Bakhshi, A. Gorgi, Forming of metallic bipolar plate with pin-type pattern by using hydroforming process in convex die, Modares Mechanical Engineering, 14(10) (2014).
[25] N. Mohammadtabar, M. Bakhshi-Jooybari, S.J. Hosseinipour, A. Gorji, Study of effective parameters in hydroforming of fuel cell metallic bipolar plates with parallel serpentine flow field, Modares Mechanical Engineering, 14(8) (2014).
[26] R. Kolahdooz, S. Asghari, S. Rashid-Nadimi, A. Amirfazli, Integration of finite element analysis and design of experiment for the investigation of critical factors in rubber pad forming of metallic bipolar plates for PEM fuel cells, International Journal of Hydrogen Energy, 42(1) (2017) 575-589.
[27] S. Mahabunphachai, Ö.N. Cora, M. Koç, Effect of manufacturing processes on formability and surface topography of proton exchange membrane fuel cell metallic bipolar plates, Journal of Power Sources, 195(16) (2010) 5269-5277.
[28] E. Dur, Ö.N. Cora, M. Koç, Effect of manufacturing conditions on the corrosion resistance behavior of metallic bipolar plates in proton exchange membrane fuel cells, Journal of Power Sources, 196(3) (2011) 1235-1241.
[29] Y. Aue-U-Lan, G. Ngaile, T. Altan, Optimizing tube hydroforming using process simulation and experimental verification, Journal of Materials Processing Technology, 146(1) (2004) 137-143.