Advanced hydrogen energy materials, electrochemical cells, and commercialization pathways in one reference Bridging laboratory-scale catalyst development and industrial-scale membrane electrode assembly manufacturing remains a central challenge in hydrogen energy research. Hydrogen Production, Storage, and Utilization: From Materials to Systems Design and Commercialization, edited by Siyu Ye, a Fellow of the Canadian Academy of Engineering, provides a rigorous treatment of advanced materials for HOR, HER, ORR, and OER reactions alongside electrochemical cell design for both low-temperature and high-temperature operation. The book reviews fundamentals, current bottlenecks, and future perspectives for key electrocatalytic materials used in fuel cells and water electrolysis. It details state-of-the-art characterization methods including synchrotron radiation and in-situ FTIR, examines artificial intelligence applications in materials and device development, and analyzes industrial production data to map commercialization progress in large-scale membrane electrode assembly manufacturing. Readers will also find: Systematic coverage of catalyst layer and MEA design principles for protonic exchange membrane fuel cells and electrolysis cellsDetailed analysis of research advancements, technical bottlenecks, and remaining challenges across hydrogen energy material classesState-of-the-art characterization techniques including synchrotron radiation and in-situ FTIR applied to hydrogen energy systemsExploration of artificial intelligence methods accelerating the discovery and optimization of electrocatalytic materials and devicesIndustrial production data analysis presenting current developments in large-scale commercialization of hydrogen energy technologies Materials scientists, electrochemists, solid state chemists, and physical chemists will find this reference directly applicable to their research and development work. By connecting electrocatalyst fundamentals with systems-level design and commercialization data, the book serves as a critical resource for advancing hydrogen energy technologies from the laboratory to industrial deployment.
