In the first two years of the project, BLESSED has made substantial progress in advancing multi-scale modelling of PEMFC devices.
The scientific work has focused on advancing predictive capabilities across different length and time scales as a starting point of the multi-scale modelling. All doctoral candidates have initiated computational approaches tailored to their individual research projects including, but not limited to, membrane degradation modelling, transport modelling in porous media and electrochemical model of PEMFC cathode. A wide range of tools—such as OpenFOAM, LAMMPS, VASP, SIESTA, and ABAQUS—were employed to develop models spanning CFD simulations, MD studies of Nafion membranes, Pt catalyst chemistry, cDFT calibration, and DEM modelling of catalyst layers. Notable achievements include successful validation of the computational models, creation of machine learning interatomic potentials (MLIPs), and coupling of structural and fluid dynamics models, laying the foundation for integrated multi-scale workflows.
Work has been progressing also on the development of Machine-learning inspired models for PEMFC components, with initial efforts focused on data generation by molecular dynamics models and identification of key descriptors for PEMFC components. Several doctoral candidates are working on descriptor identification to enable accurate structure-to-property predictions, particularly for solid-liquid-gas (SLG) interactions relevant to electrocatalytic activity and transport properties. Advanced ML techniques—including convolutional neural networks (CNNs), Fourier neural operators (FNOs), physics-informed neural networks (PINNs), Gaussian process regression (GPR), support vector regression (SVR), random forest (RF) regressors, and deep neural networks (DNNs)—have been applied to learn transport coefficients, capture structure-property relationships, and optimize gas diffusion layer (GDL) microstructure.
These developments lay the groundwork for data-driven models that enhance predictive accuracy and accelerate design optimization across PEMFC components.