Ceramic Hydrogen Storage Materials presents the physical, chemical, physico-chemical properties of ceramics as HSMs. It demonstrates how ceramic nanostructures can be specially designed for high surface adsorption of hydrogen and act as hydrogen batteries.
Ceramic Hydrogen Storage Materials presents the physical, chemical, physico-chemical properties of ceramics as hydrogen storage materials. It demonstrates how ceramic nanostructures can be specifically designed for high surface adsorption of hydrogen and can function as hydrogen batteries.
Covering methods for characterizing hydrogen storage capacity, this book showcases how hydrogen has the potential to facilitate decarbonization of the electric power sector by storing energy produced from renewable sources. It addresses both ceramic oxides and non-oxides while expanding on the synthesis and characterization of zero- and one-dimensional, high-surface-area ceramic structures. This book discusses the applications of hydrogen batteries in zero-emission vehicles and hydrogen fuels for aircraft.
This book will interest upper-level undergraduate energy and materials engineering students, as well as researchers studying green energy storage materials, hydrogen storage, and alternative transportation fuels.
1. Hydrogen Gas: Future Green Energy Source.
2. Ceramics: Structures,
Types, and Properties.
3. Gas Adsorption: Thermodynamics and Kinetics.
4.
Hydrogen Adsorption.
5. Hydrogen Storage: Ceramic Hydrogen Batteries.
6.
Analysis and Assessment Challenges, Opportunities and Future.
Dr. Navid Hosseinabadi is currently a faculty member at Shiraz University, Iran. He specializes in advanced ceramics science and engineering. His research interests focus on developing solid-state inorganic hydrogen storage materials as hydrogen batteries from ceramics, including nanoparticles, nanocapsules, MXenes, and ceramic substrates.
