Features
Gives in-depth, real-world context to the technical content, explaining how and why hydrogen technology must be a part of future energy systems
Discusses the progress in developing fuel cells and hydrogen combustion engines to convert hydrogen to power
Describes all hydrogen storage methods, including high-pressure gas, cryogenic, cryo-compressed, metal hydride, sorption, chemical hydrides, and liquid organic hydrogen carriers
Explores the state of the art in hydrogen storage engineering
Presents the latest hydrogen codes and standards'essential information for anyone involved in developing hydrogen-powered energy systems
Summary
Zero-carbon, hydrogen-based power technology offers the most promising long-term solution for a secure and sustainable energy infrastructure. With contributions from the worlds leading technical experts in the field, Hydrogen Storage Technology: Materials and Applications presents a broad yet unified account of the various materials science, physics, and engineering aspects involved in storing hydrogen gas so that it can be used to provide power. The book helps you understand advanced hydrogen storage materials and how to build systems around them.
Accessible to nonscientists, the first chapter explains how a hydrogen-based energy carrier and storage infrastructure is required to address fuel resource and political insecurities as well as global climate change. The second chapter describes high-efficiency hydrogen conversion devices, including internal combustion engines and fuel cells, for producing power and electricity.
The book then dives into the state of the art in hydrogen storage technology. It covers recent hydrogen storage materials research and hydrogen storage methods, with an emphasis on solid-state techniques. It also reviews codes and standards and explores engineering approaches for creating zero-emission, hydrogen-fueled power systems.
Collecting recent results from around the globe, this book gets you up to date on the latest hydrogen-based technology for mitigating energy and environmental risks. It provides a deep science and engineering-based description of hydrogen storage materials and clearly explains how the materials are engineered for zero-emission, carbon-free power systems
The Need for Hydrogen in the 21st Century and Devices for Converting It to Power
The Need for Hydrogen-Based Energy Technologies in the 21st Century, Jay Keller, Lennie Klebanoff, Susan Schoenung, and Mary Gillie
Hydrogen Conversion Technologies and Automotive Applications, Lennie Klebanoff, Jay Keller, Matt Fronk, and Paul Scott
Hydrogen Storage Materials and Technologies
Historical Perspectives on Hydrogen, Its Storage, and Its Applications, Bob Bowman, Jr. and Lennie Klebanoff
Hydrogen Storage in Pressure Vessels: Liquid, Cryogenic, and Compressed Gas, Guillaume Petitpas and Salvador Aceves
Hydrogen Storage in Interstitial Metal Hydrides, Ben Chao and Lennie Klebanoff
Development of Onboard Reversible Complex Metal Hydrides for Hydrogen Storage, Vitalie Stavila, Lennie Klebanoff, John Vajo, and Ping Chen
Storage Materials Based on Hydrogen Physisorption, Justin Purewal and Channing Ahn
Development of Off-Board Reversible Hydrogen Storage Materials, Jason Graetz, David Wolstenholme, Guido Pez, Lennie Klebanoff, Sean McGrady, and Alan Cooper
Engineered Hydrogen Storage Systems: Materials, Methods, and Codes and Standards
Engineering Properties of Hydrogen Storage Materials, Daniel Dedrick
Solid-State H2 Storage System Engineering: Direct H2 Refueling, Terry Johnson and Pierre Bénard
Engineering Assessments of Condensed-Phase Hydrogen Storage Systems, Bob Bowman, Jr., Don Anton, and Ned Stetson
Codes and Standards for Hydrogen Storage in Vehicles, Christine Sloane
Index