Additionally, the vital role MOFs play in energy storage, environmental purification, including degradation of harmful agents, and resource utilization is explored. The book also presents new research on machine learning and data mining, including how researchers can leverage datasets and algorithms to discover new, high-performance MOFs. Metal Organic Frameworks for Energy and Environmental Applications will be a valuable reference for those studying and working in the field of MOFs as they apply to energy, environmental technologies, catalysis, and materials science.
Table of Contents
1. Introduction to MOFs2. Synthetic strategies for MOFs
3. Characterization techniques for MOFs
4. Shaping of metal-organic framework
5. MOFs for photocatalytic water splitting
6. MOFs for photocatalytic CO2 reduction
7. MOFs for HER and OER
8. MOFs for CO2 electroreduction
9. MOFs for oxidation and hydrogenation reaction
10. MOFs for thermal energy storage
11. MOFs for electrical energy storage
12. MOFs for hydrogen storage
13. MOFs for chemical warfare agent degradation
14. MOFs for gas sensor
15. MOFs for extraction of radionuclide/noble metals/lithium
16. Machine learning accelerates the development of MOFs
17. Conclusions and challenges
Authors
Hongyi Gao University of Science and Technology Beijing, China.Dr. Gao has been responsible for many research projects sponsored by the National Key Research and Development Program, National Natural Science Foundation, etc. She has published more than 100 SCI papers in a variety of journals, including Coordination Chemistry Reviews, Applied Catalysis B: Environmental, Nano Today, ACS Catalysis, Nano Energy, etc. Furthermore, he has had 30 national invention patents authorized.
Xiaowei Zhang Beijing Normal University, China.Prof Zhang's research interests mainly focuses on organic-inorganic hybrid materials and their applications in energy storage, catalysis, and optoelectronics. Her current research emphasizes the design of new catalysts and control of morphology, microstructure, and reaction mechanism for CO2 conversion, hydrogen production, degradation, etc. Some of her recent progress includes novel approaches to designing multifunctional phase change materials for thermal energy storage and photothermal energy conversion with high energy-utilizing efficiency.
Dr. Zhang has been responsible for many research projects sponsored by the National Natural Science Foundation, Beijing Natural Science Foundation, etc. She has published more than 50 peer-reviewed papers, including Advanced Materials, Chemical Engineering Journal, Aggregate, Journal of Materials Chemistry A, etc. Furthermore, she has had 18 national invention patents authorized.