Heat and Mass Transfer Considerations for Advancing Fuel cells and Electrolyzers

Hydrogen continues to gain traction as an energy carrier of the future, and fuel cells provide the ideal partner technology – using hydrogen fuel to produce on-demand, zero-emission power. However, there are still key challenges to commercializing fuel cells and electrolyzers for clean energy. In this talk, I will discuss our consideration of heat and mass transfer for several materials over a range of length scales, and how these considerations are important for informing next generation device development. I will discuss how our work from the flow field and gas diffusion layer have informed our approach to the catalyst coated membrane.    I will then focus on X-ray techniques that provide high spatial and temporal resolution for examining experimental performance and materials characterization. I will discuss the advancement we are making in characterizing the spatio-chemical speciation of custom catalyst layers. Specifically, we probe the carbon, fluorine, and oxygen spectral K-edges on commercial catalyst layers using near-edge X-ray absorption fine structure spectroscopy (NEXAFS) in conjunction with scanning transmission X-ray microscopy (STXM) to provide a comprehensive two-dimensional map of the PEM fuel cell catalyst layer. I will discuss the structural characteristics of the CL, which will be highly valuable for informing the design of next generation PEM fuel cell catalyst layers.