Pore network model of the cathode catalyst layer of proton exchange membrane fuel cells: Analysis of water management and electrical performance

Doped tin dioxide aerogel as alternative catalyst support for Proton Exchange Membrane Fuel Cells.. Guillaume Ozouf,

Gerteisen, Modeling the liquid water transport in the gas diffusion layer for polymer electrolyte membrane fuel cells using a water path network, Energy 6 (2013) 4508–4530.

From these findings, we conclude that the regular pore network comprising primary and secondary pore networks is acceptable to represent the microstructure of fuel cell catalyst

Proton exchange membrane fuel cells; Platinum catalyst loading; Patterned membrane electrode assembly.. Proton exchange membranes were nano- and micro-patterned on their cathode

Fig. Quantitative comparison of experimental water distribution with water dis- tribution simulated with full morphology and pore networks. a) Full lines: sample averaged voxel match

Gerteisen, Modeling the liquid water transport in the gas diffusion layer for polymer electrolyte membrane fuel cells using a water path network, Energy 6 (2013) 4508–4530.

Combining proper morphology (high specific surface area and adequate pore size distribution) and high electronic conductivity is mandatory for a material to be a

Performance loss of proton exchange membrane fuel cell due to hydrophobicity loss in gas diffusion layer: Analysis by multiscale approach combining pore network and