Pourrahmani, HosseinHosseini, MiladMoussaoui, HamzaOveisi, EmadSiavashi, MajidVan Herle, Jan2024-07-032024-07-032024-07-032024-04-2610.1038/s41598-024-60148-whttps://infoscience.epfl.ch/handle/20.500.14299/208976WOS:001211019400014In Proton Exchange Membrane Fuel Cells (PEMFCs), the presence of residual water within the Gas Diffusion Layer (GDL) poses challenges during cold starts and accelerates degradation. A computational model based on the Lattice Boltzmann Method (LBM) was developed to consider the capillary pressure inside the PEMFC and to analyze the exact geometries of the GDLs, which were obtained using the Computed Tomography scan. The novelty of this study is to suggest a methodology to compare the quantitative water removal performance of the GDLs without long-term experimental testing. Two different samples of GDLs were considered, pristine and aged. The results of quantitative measurements revealed the amount of water columns (breakthroughs) inside each sample. Considering the volume of 12,250,000 mu m3 for each sample, the pristine and the aged samples are prone to have 774,200 mu m3 (6.32%) and 1,239,700 mu m3 (10.12%) as water columns in their porous domain. Micro-structural properties such as connectivity, mean diameter, effective diffusivity, etc. were also compared to observe the impacts of aging on the properties of the GDL.Proton Exchange Membrane Fuel Cell (Pemfc)Gas Diffusion Layer (Gdl)Computed Tomography (Ct) ScanLattice Boltzmann Method (Lbm)Water Columns (Breakthrough)text::journal::journal article::research article