Description
Catalytic Reactions in Hydrogen Energy Production: Physicochemical Fundamentals elucidates the activation mechanism of molecular chemical bonds, the construction law of catalytic site orientation and the catalytic mechanism in the catalytic reaction processes involved in hydrogen energy production (including electrocatalysis, photocatalysis and thermocatalysis, summarizing the related hydrogen-producing catalytic theories (hydrogen production by water decomposition, hydrogen production by water vapor transformation, hydrogen production by methane, etc). This is to help develop a series of efficient catalysts, achieve technical breakthroughs in green hydrogen and blue hydrogen production, and innovate the catalytic theory of renewable energy to establish a theoretical database.The text is divided into four main parts dealing with: electrocatalysis, photocatalysis, thermocatalysis, and finally, hydrogen energy applications, conclusions, and outlook. There are two key aspects of hydrogen industry involved in this book:- Precise interface regulation and microscopic mechanism of heterogeneous catalysis hydrogen production systems.- Discussion of catalytic materials and theory of efficient hydrogen production and discussion on their application value and practical prospect. The authors also pay special attention to the analysis of the thermodynamic and kinetic theories of catalytic reactions, providing scientific basis for the optimization of reaction conditions and the speculation of reaction mechanism.This book is written primarily for graduate students and early researchers in the chemical sciences grounded in inorganic and physical chemistry, coordination chemistry, molecular dynamics, electrochemistry, photocatalysis, thermocatalysis, and thermodynamics. It will also be of interest to those in the adjacent fields of materials science, energy, and environmental studies looking at aspects of hydrogen production- Reference resource for knowledge on the current development status and specific applications of catalysts and nano-catalysts for hydrogen energy production- Focuses on the important but underexplored physicochemical aspects of thermodynamic and kinetic theories of catalytic reactions in the chemical reaction processes involved in hydrogen production- Demonstrates the basic principles of electrocatalytic, photocatalytic, and thermocatalytic hydrogen production and the practical application prospects- Provides comparison of different technologies including description of mechanistic aspects
Table of Contents
Part I Hydrogen energy and electrocatalysis1. Introduction to hydrogen energy and electrocatalysis2. Basic principle of hydrogen production by electrolysis of water3. Performance evaluation of hydrogen production by electrolysis of water4. Catalytic materials for electrolysis of water to hydrogen production5. Design of catalytic materials for electrolysis of water6. The coupling design of water electrolysis and other systems7. Design of other electrolytic hydrogen production system8. Results and prospects of hydrogen energy and electrocatalysisPart II Hydrogen energy and photocatalysis9. Introduction of hydrogen energy and photocatalysis10. The basic principle of photocatalysis11. Performance evaluation of hydrogen production by photolysis of water12. Catalytic materials for photocatalysis13. Design of catalytic materials for photocatalysis of water splitting14. Results and prospects of hydrogen energy and photocatalysisPart III Hydrogen energy and thermocatalysis thermocatalysis15. Introduction of hydrogen energy and thermocatalysis16. Principle and catalyst of hydrogen production by water gas shift17. Principle and catalyst of methane reforming hydrogen production18. Principle and catalyst of methanol reforming hydrogen production19. Results and prospects of hydrogen energy and thermocatalysisPart IV Life cycle assessments and Practical application Aspects20. Life cycle assessment of Hydrogen Energy Technology21. Practical industrial technologies of hydrogen Production22. Practical industrial application of Hydrogen energyPart V conclusions and outlooks23. Conclusions and outlooks of this book
