Description
Book SynopsisCleavage of water to its constituents (i.e., hydrogen and oxygen) for production of hydrogen energy at an industrial scale is one of the holy grails of materials science. That can be done by utilizing the renewable energy resource i.e. sunlight and photocatalytic material. The sunlight and water are abundant and free of cost available at this planet. But the development of a stable, efficient and cost-effective photocatalytic material to split water is still a great challenge. To develop the effective materials for photocatalytic water splitting, various type of materials with different sizes and structures from nano to giant have been explored that includes metal oxides, metal chalcogenides, carbides, nitrides, phosphides, and so on. Fundamental concepts and state of art materials for the water splitting are also discussed to understand the phenomenon/mechanism behind the photoelectrochemical water splitting. This book gives a comprehensive overview and description of the manufactu
Trade Review
"...presents an exhaustive literature related to hydrogen generation from splitting of water by various methods. It will be welcomed by researchers as it fulfills the demand of the day."
— Suresh C. Ameta, Paher University, Udaipur, India
"...interesting not only to experts but also to beginners and students in the field of photoelectrochemical water splitting. The content covered will attract the broad readership in solar fuels from academia, and government to industry."
— Nick Wu, West Virginia University, USA
"Any courses related to Renewable Energy (as well as functional materials and solid state physics applications) could use this book. Prof. Ru-Shi Liu is a well-known scientist and highly cited in this field, so the materials presented are indeed trustworthy and of high quality."
— Lionel Vayssieres, Xian Jiaotong University, China
Table of ContentsIntroduction to hydrogen as a green fuel. Concepts and definitions in photochemical water splitting. Water splitting technologies for hydrogen generation. Electrochemical water splitting. Oxide semiconductors (ZnO, TiO2, Fe2O3, WO3, etc) as photocatalysts for water splitting. Non oxide semiconductor materials for water splitting. Nanostructured semiconducting materials for water splitting. Giant sized materials for water splitting (supramolecular, dendrimers composite, etc). Fundamental understanding of the photocatalytic mechanisms. Photochemical cell designs, fabrication, performance, degradation, and diagnosis for efficient solar hydrogen production.
