PEM Electrolysis for Hydrogen Production: Principles and Applications
Editat de Dmitri Bessarabov, Haijiang Wang, Hui Li, Nana Zhaoen Limba Engleză Paperback – 26 iul 2017
Written by international scientists in PEM electrolysis and fuel cell research areas, this book addresses the demand for energy storage technologies that store intermittent renewable energy and offers the most complete and up-to-date information on PEM electrolysis technology and research.
The authors:
- Cover the fundamental applications of PEM electrolysis
- Review the state-of-the-art technologies and challenges related to each of the components of the PEM electrolysis
- Address failure analysis and review available failure diagnostic tools
- Provide future direction for researchers and technology developers
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Specificații
ISBN-13: 9781138775497
ISBN-10: 1138775495
Pagini: 404
Ilustrații: 337
Dimensiuni: 210 x 280 x 22 mm
Greutate: 1.06 kg
Ediția:1
Editura: CRC Press
Colecția CRC Press
ISBN-10: 1138775495
Pagini: 404
Ilustrații: 337
Dimensiuni: 210 x 280 x 22 mm
Greutate: 1.06 kg
Ediția:1
Editura: CRC Press
Colecția CRC Press
Cuprins
Overview of PEM Electrolysis for Hydrogen Production. Fundamentals of PEM Water Electrolysis. Electrocatalysts for Oxygen Evolution Reaction. Electrocatalysts for the Hydrogen Evolution Reaction. NSTF for PEM Water Electrolysis. Membrane. Bipolar Plates and Plate Materials. Current Collectors (GDLs) and Materials. Proton Exchange Membrane Electrolyzer Stack and System Design. Characterization Tools for Polymer Electrolyte (PEM) Water Electrolyzers. Degradation Processes and Failure Mechanisms in PEM Water Electrolyzers. Modeling of PEM Water Electrolyzer. Fundamentals of Electrochemical Hydrogen Compression. Large-Scale Water Electrolysis for Power-to-Gas. Depolarized Proton Exchange Membrane Water Electrolysis: Coupled Anodic Reactions. Generation of Ozone and Hydrogen in a PEM Electrolyzer. Isotope Separation Using PEM Electrochemical Systems.
Notă biografică
Dr. Dmitri Bessarabov joined the Department of Science and Technology Hydrogen South Africa (HySA) Infrastructure Center of Competence at North-West University and the Council for Scientific and Industrial Research in 2010. His research covers hydrogen and electro-catalytic membrane systems for energy applications and fuel cells. In 1991, Dr. Bessarabov received his M.Sc in chemistry at Lomonosov Moscow State University in Russia before continuing his studies at the Topchiev Institute of Petrochemical Synthesis of the Russian Academy of Sciences. In 1993, he joined the Ph.D program at the Institute for Polymer Science, University of Stellenbosch in South Africa, where he received his Ph.D in 1996.
Dr. Haijiang Wang is a principle research officer and project manager in the National Research Council of Canada. He received his Ph.D in electrochemistry from the University of Copenhagen, Denmark, in 1993. He then joined Dr. Vernon Parker’s research group at Utah State University as a postdoctoral researcher to study electrochemically generated anion and cation radicals. Dr. Wang is adjunct professor at five universities, including the University of British Columbia and the University of Waterloo. He has published more than 160 journal papers, three books, ten book chapters, numerous reports, conference papers, and presentations, and has been issued five patents.
Dr. Hui Li is a research officer and a program technical lead under the energy storage program at the National Research Council of Canada (NRC). She received her BS and M.Sc in chemical engineering from Tsinghu University in 1987 and 1990, respectively. In 2006, she obtained her Ph.D in electrochemical engineering at the University of British Columbia, Canada. Since joining NRC in 2007, Dr. Li has been working on polymer electrolyte membrane (PEM) fuel cell contamination and durability, PEM electrolysis, and zinc-air batteries. She has co-authored more than 45 research papers published in refereed journals and co-edited three books related to PEM fuel cells.
Dr. Nana Zhao is a research scientist at Vancouver International CleanTech Research Institute Inc. She received her BS on polymer chemistry and physics at Beijing Normal University in 2000. After that, she started her Ph.D program on polymer chemistry and physics at the Changchun Institute of Applied Chemistry, Chinese Academic Sciences, in 2002. After obtaining her Ph.D in 2008, she joined Professor Ting Xu’s group as postdoctoral fellow in material science and engineering at the University of California, Berkeley. At the same time, she also worked with Professor Frantisek Svec’s team in molecular foundry at Lawrence Berkeley National Laboratory.
Dr. Haijiang Wang is a principle research officer and project manager in the National Research Council of Canada. He received his Ph.D in electrochemistry from the University of Copenhagen, Denmark, in 1993. He then joined Dr. Vernon Parker’s research group at Utah State University as a postdoctoral researcher to study electrochemically generated anion and cation radicals. Dr. Wang is adjunct professor at five universities, including the University of British Columbia and the University of Waterloo. He has published more than 160 journal papers, three books, ten book chapters, numerous reports, conference papers, and presentations, and has been issued five patents.
Dr. Hui Li is a research officer and a program technical lead under the energy storage program at the National Research Council of Canada (NRC). She received her BS and M.Sc in chemical engineering from Tsinghu University in 1987 and 1990, respectively. In 2006, she obtained her Ph.D in electrochemical engineering at the University of British Columbia, Canada. Since joining NRC in 2007, Dr. Li has been working on polymer electrolyte membrane (PEM) fuel cell contamination and durability, PEM electrolysis, and zinc-air batteries. She has co-authored more than 45 research papers published in refereed journals and co-edited three books related to PEM fuel cells.
Dr. Nana Zhao is a research scientist at Vancouver International CleanTech Research Institute Inc. She received her BS on polymer chemistry and physics at Beijing Normal University in 2000. After that, she started her Ph.D program on polymer chemistry and physics at the Changchun Institute of Applied Chemistry, Chinese Academic Sciences, in 2002. After obtaining her Ph.D in 2008, she joined Professor Ting Xu’s group as postdoctoral fellow in material science and engineering at the University of California, Berkeley. At the same time, she also worked with Professor Frantisek Svec’s team in molecular foundry at Lawrence Berkeley National Laboratory.
Recenzii
"This is a very useful reference book for a variety of people involved in research and application of PEM electrolysers."
—Sam Suppiah, Canadian Nuclear Laboratories
"This is the most complete and up-to-date review of PEM Electrolysis. It provides an excellent summary of the advantages of hydrogen as an energy storage and carrier medium as we move to a greater reliance on renewable and intermittent power sources. It not only touts the many advantages of PEM electrolyzers for large-scale energy storage, but it also presents the many technical and economic challenges in bringing these systems to market."
—John W. Weidner, University of South Carolina
—Sam Suppiah, Canadian Nuclear Laboratories
"This is the most complete and up-to-date review of PEM Electrolysis. It provides an excellent summary of the advantages of hydrogen as an energy storage and carrier medium as we move to a greater reliance on renewable and intermittent power sources. It not only touts the many advantages of PEM electrolyzers for large-scale energy storage, but it also presents the many technical and economic challenges in bringing these systems to market."
—John W. Weidner, University of South Carolina
Descriere
There is increasing research interest in producing hydrogen through polymer electrolyte membrane (PEM) electrolysis as a way of converting renewable energy to hydrogen fuel. This book provides comprehensive coverage of the fundamentals and applications of PEM electrolysis and reviews state-of-the-art technologies and challenges related to each of the components. In addition, the text addresses failure analysis and describes available failure diagnostic tools while providing future research directions to assist scientists and technology developers in bringing commercially viable PEM electrolysis systems to fruition.