[1] William Grubb (1959) Proceedings of the 11th Annual Battery Research and Development conference, PSC Publications Committee, Red Bank, NJ, p. 5, 1957; U.S. Patent No. 2,913,511.
[2] Sandip D, Shimpalee S, Van Zee JW (2000) Threedimensional numerical simulation of straight channel PEM fuel cells. J Appl Electrochem 30(2): 135-146.
[3] Torsten B, Djilali N (2003) Three-dimensional computational analysis of transport phenomena in a PEM fuel cell—a parametric study. J Power Sources 124(2): 440-452.
[4] Ahmadi N, Rezazadeh S, Dadvand A, Mirzaee I (2017) Study of the effect of gas channels geometry on the performance of polymer electrolyte membrane fuel cell. periodica polytechnica chemical engineering. Period Polytech-Chem 62(1).
[5] Majidifar S, Mirzaei I, Rezazadeh S, Mohajeri P, Oryani H (2011) Effect of gas channel geometry on performance of PEM fuel cells. Aust J Basic Appl Sci 5(5): 943-954.
[6] Pourmahmoud N, Rezazadeh S, Mirzaee I, Heidarpoor V (2011) Three-dimensional numerical analysis of proton exchange membrane fuel cell. J Mech Sci Technol 25(1): 2665.
[7] Ahmadi N, Pourmahmoud N, Mirzaee I, Rezazadeh S (2011) Three-dimensional computational fluid dynamic study of effect of different channel and shoulder geometries on cell performance. Aust J Basic Appl Sci 5(12): 541-556.
[8] Ahmadi N, Rezazadeh S, Mirzaee I, Pourmahmoud N (2012) Three-dimensional computational fluid dynamic analysis of the conventional PEM fuel cell and investigation of prominent gas diffusion layers effect. J Mech Sci Technol 26(8): 2247-2257.
[9] Lee CS, Yi SC (2004) Numerical methodology for proton exchange membrane fuel cell simulation using computational fluid dynamics technique. Korean J Chem Eng 21(6): 1153-1160.
[10] Yang TH, Park GG, Pugazhendhi P, Lee WY, Kim CS (2002) Performance improvement of electrode for polymer electrolyte membrane fuel cell. Korean J Chem Eng 19(3): 417-420.
[11] Molaeimanesh G, Akbari MH (2014) Water droplet dynamic behavior during removal from a proton exchange membrane fuel cell gas diffusion layer by Lattice-Boltzmann method. Korean J Chem Eng 31(4):598-610.
[12] Carral C, Mélé P (2014) A numerical analysis of stack assembly through a 3D finite element model. Int J Hydrogen Energ 39(9):4516-4530.
[13] Jung CY, Kim JJ, Lim SY, Yi SC (2007) Numerical investigation of the permeability level of ceramic bipolar plates for polymer electrolyte fuel cells. J Ceram Process Res 8(5): 369.
[14] Pourmahmud N, Rezazadeh S, Mirzaei I, Motalleb S (2012) A computational study of PEMFC with conventional and deflected MEA. J Mech Sci Technol 26(9): 2959-2968.
[15] Ahmadi N, Rezazadeh S, Mirzaee I (2015) Study the effect of various operating parameters of proton exchange membrane. Period Polytech-Chem (3): 221.
[16] Rajabian H, Amiri H, Rahimi M, Marashi SMB, Arab Solghar A (2015) Experimentaland numerical analysis of PEM fuel cell performance with a new helically symmetrical flow channel. Journal of Solid and Fluid Mechanics. Shahrood university.
[17] Atyabi SA, Afshari E (2013) Effect of GDL porosity and pressure on the PEM fuel cell performance with honeycomb flow-field. Journal of Solid and Fluid Mechanics. Shahrood university.
[18] Sheikhmohammadi A, Mirzaee I, Pormahmod N, Ahmadi N (2019) Influence of gas channels and gas diffusion layers configuration on the performance of polymer electrolyte membrane fuel cell. Journal of Solid and Fluid Mechanics. Shahrood university.
[19] Dewan HA, Hyung JS (2006) Effects of channel geometrical configuration and shoulder width on PEMFC performance at high current density. J Power Sources 162(1): 327-339.
[20] Jung CY, Kim JJ, Lim SY, Yi SC (2007) Numerical investigation of the permeability level of ceramic bipolar plates for polymer electrolyte fuel cells. J Ceram Process Res 8: 369-375.
[21] Wang L, Husar A, Zhou T, Liu H (2003) A parametric study of PEM fuel cell performances. Int J Hydrogen Energ 28(11): 1263-1272.
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