Fluorinated Materials for Energy Conversion
- 1st Edition - May 20, 2005
- Editors: Tsuyoshi Nakajima, Henri Groult
- Language: English
- Hardback ISBN:9 7 8 - 0 - 0 8 - 0 4 4 4 7 2 - 7
- eBook ISBN:9 7 8 - 0 - 0 8 - 0 5 3 1 7 8 - 6
Fluorinated Materials for Energy Conversion offers advanced information on the application of fluorine chemistry to energy conversion materials for lithium batteries, fuel cells,… Read more
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Request a sales quoteFluorinated Materials for Energy Conversion offers advanced information on the application of fluorine chemistry to energy conversion materials for lithium batteries, fuel cells, solar cells and so on. Fluorine compounds and fluorination techniques have recently gained important roles in improving the electrochemical characteristics of such energy production devices. The book therefore focuses on new batteries with high performance, the improvements of cell performance and the improvement of electrode and cell characteristics. The authors present new information on the effect of fluorine and how to make use of fluorination techniques and fluorine compounds. With emphasis on recent developments, this book is suitable for students, researchers and engineers working in chemistry, materials science and electrical engineering.
- Contains practical information, supported by examples
- Provides an update on recent developments in the field
- Written by specialists working in fluorine chemistry, electrochemistry, polymer and solid state chemistry
Academic and industrial researchers, technicians and graduate students interested in fundamental and/or applied research in Chemistry, Materials science and Electrical engineering
Chapter 1. Experimental and theoretical aspects of the fluorine evolution reaction on carbon anodes in molten KF-2HF (H. Groult et al.).
Chapter 2. Applications of fluorinated carbon materials to primary and secondary lithium batteries
(Tsuyoshi Nakajima).
Chapter 3. Synthesis and electrochemical properties of new carbon anodes prepared by chemical vapor infiltration (Yoshimi Ohzawa).
Chapter 4. Electrochemical properties of fluorinated carbon nanotubes (Hidekazu Touhara).
Chapter 5. Fluorine-doped tin oxide electrodes for lithium batteries (Chai-Won Kwon et al.).
Chapter 6. Synthesis of fluorinated cathodes and fluoride electrolytes for lithium ion battery
(Susumu Yonezawa, Masayuki Takashima).
Chapter 7. Physicochemical properties of fluorine-containing electrolytes for lithium batteries
(D. Lemordant et al.).
Chapter 8. Fluorinated anions and electrode/electrolyte stability in lithium batteries
(R. Yazami).
Chapter 9. Electrochemical properties of lithium electrolytes based on bis(polyfluorodiolato)borate and tetrakis(polyfluoroalkoxy)aluminate superweak anions (B.G. Nolan et al.).
Chapter 10. Fluorinated electrolytes based on lithium salts of strong Bronsted acids
(O.E. Geiculescu et al.).
Chapter 11. Electrolytes for lithium batteries
(Kiyoshi Kanamura).
Chapter 12. Thermally stable fluoro-organic solvents for lithium ion battery
(Jun-ichi Yamaki).
Chapter 13. Physical and electrochemical properties and application to lithium batteries of fluorinated organic solvents (Yukio Sasaki).
Chapter 14. PVdF based polymers for lithium batteries (J.-Y. Sanchez et al.).
Chapter 15. Lithium-ion-conductive polymer electrolytes exhibit a high lithium-ion transference number with the incorporation of fluorine atoms (Takeshi Abe, Zempachi Ogumi).
Chapter 16. Room temperature molten salts as new electrolytes (Rika Hagiwara, Kazuhiko Matsumoto).
Chapter 17. Fluorine-intercalated graphite for lithium batteries (A. Hamwi et al.).
Chapter 18. Battery application of graphite intercalation compounds (Yoshiaki Matsuo).
Chapter 19. Fluoride-based electrolytes and their applications for intermediate temperature ceramic fuel cells (Bin Zhu, Bengt-Erik Mellander).
Chapter 20. The use of Nafion in fuel cells
(M. Odgaard).
Chapter 21. Functional fluoropolymers for fuel cell membranes (R. Souzy, B. Améduri).
Chapter 22. Films and powders of fluorine-doped tin dioxide (H. Cachet).
Chapter 23. Doped transparent conducting oxides suitable for the fabrication of high efficiency thin film solar cells (A. Bosio et al.).
Chapter 24. Fluoride technologies application within the Molten-Salt Reactors fuel (J. Uhlir).
Chapter 2. Applications of fluorinated carbon materials to primary and secondary lithium batteries
(Tsuyoshi Nakajima).
Chapter 3. Synthesis and electrochemical properties of new carbon anodes prepared by chemical vapor infiltration (Yoshimi Ohzawa).
Chapter 4. Electrochemical properties of fluorinated carbon nanotubes (Hidekazu Touhara).
Chapter 5. Fluorine-doped tin oxide electrodes for lithium batteries (Chai-Won Kwon et al.).
Chapter 6. Synthesis of fluorinated cathodes and fluoride electrolytes for lithium ion battery
(Susumu Yonezawa, Masayuki Takashima).
Chapter 7. Physicochemical properties of fluorine-containing electrolytes for lithium batteries
(D. Lemordant et al.).
Chapter 8. Fluorinated anions and electrode/electrolyte stability in lithium batteries
(R. Yazami).
Chapter 9. Electrochemical properties of lithium electrolytes based on bis(polyfluorodiolato)borate and tetrakis(polyfluoroalkoxy)aluminate superweak anions (B.G. Nolan et al.).
Chapter 10. Fluorinated electrolytes based on lithium salts of strong Bronsted acids
(O.E. Geiculescu et al.).
Chapter 11. Electrolytes for lithium batteries
(Kiyoshi Kanamura).
Chapter 12. Thermally stable fluoro-organic solvents for lithium ion battery
(Jun-ichi Yamaki).
Chapter 13. Physical and electrochemical properties and application to lithium batteries of fluorinated organic solvents (Yukio Sasaki).
Chapter 14. PVdF based polymers for lithium batteries (J.-Y. Sanchez et al.).
Chapter 15. Lithium-ion-conductive polymer electrolytes exhibit a high lithium-ion transference number with the incorporation of fluorine atoms (Takeshi Abe, Zempachi Ogumi).
Chapter 16. Room temperature molten salts as new electrolytes (Rika Hagiwara, Kazuhiko Matsumoto).
Chapter 17. Fluorine-intercalated graphite for lithium batteries (A. Hamwi et al.).
Chapter 18. Battery application of graphite intercalation compounds (Yoshiaki Matsuo).
Chapter 19. Fluoride-based electrolytes and their applications for intermediate temperature ceramic fuel cells (Bin Zhu, Bengt-Erik Mellander).
Chapter 20. The use of Nafion in fuel cells
(M. Odgaard).
Chapter 21. Functional fluoropolymers for fuel cell membranes (R. Souzy, B. Améduri).
Chapter 22. Films and powders of fluorine-doped tin dioxide (H. Cachet).
Chapter 23. Doped transparent conducting oxides suitable for the fabrication of high efficiency thin film solar cells (A. Bosio et al.).
Chapter 24. Fluoride technologies application within the Molten-Salt Reactors fuel (J. Uhlir).
- No. of pages: 592
- Language: English
- Edition: 1
- Published: May 20, 2005
- Imprint: Elsevier Science
- Hardback ISBN: 9780080444727
- eBook ISBN: 9780080531786
TN
Tsuyoshi Nakajima
Tsuyoshi Nakajima is Professor in the Department of Applied Chemistry, Aichi Institute of Technology in Japan. He has worked on fluorine chemistry and electrochemistry (that is, fluorinated materials) for primary and rechargeable lithium batteries, and fluorine-, fluoride-, or oxyfluoride-graphite intercalation compounds. Li/(CF)n battery is the first primary lithium battery commercialized on the basis of the research on graphite fluoride which was performed in his laboratory at Kyoto University. His research was on the discharge mechanism of Li/(CF)n battery and synthesis of graphite fluoride, (CF)n with excellent discharge performance. The importance of carbon-fluorine compounds as battery materials was first recognized by graphite fluoride cathode of Li/(CF)n battery. Furthermore, new graphite anode for electrolytic production of fluorine gas was developed on the basis of his work on fluorine-graphite intercalation compound with high electrical conductivity. Recently. his research interest is on the application of fluorine chemistry to rechargeable lithium batteries. Fluorination techniques were applied to surface modification of graphite anode which increases the capacities of graphite anode and enables the low temperature operation of lithium ion battery. For the application of lithium ion battery using flammable organic solvents to electric sources of hybrid and electric vehicles, high safety is the most important issue. He has found that organo-fluorine compounds are excellent new solvents with high oxidation stability (that is, high safety for rechargeable lithium batteries). He published about 230 papers and 24 books. In academic societies, he served as chairman of JSPS 155th Committee on Fluorine Chemistry; The Society of Fluorine Chemistry, Japan; Executive Committee of Carbon Society of Japan; and Regional Editor and Editorial Board of J. Fluorine Chemistry.
Affiliations and expertise
Aichi Institute of Technology, Toyota, JapanHG
Henri Groult
Henri Groult is Director of Research of CNRS-UPMC-ESPCI UMR 7612, University of Pierre and Marie Curie (Paris 6) in France. He has devoted his research life to fluorine chemistry, electrochemistry, and molten salt chemistry. His main research subjects are electrolytic production of fluorine gas, fluorine compounds for primary and secondary lithium batteries, and electrochemical properties of molten fluorides and chlorides. He has obtained interesting results on fluorine evolution reaction on carbon electrodes, discharge behavior of carbon-fluorine compounds, charge/discharge characteristics of metal fluorides, and electrochemical properties of molten salts. On these subjects, he published more than 100 papers and 7 books. His activity has played an important role in fluorine chemistry in France. He has served as Director of the French Network of Fluorine, Chairman of the 17th European Symposium on Fluorine Chemistry (Paris, July 2013), and Editorial board of J. Fluorine Chemistry.
Affiliations and expertise
University of Pierre and Marie Curie, Paris, FranceRead Fluorinated Materials for Energy Conversion on ScienceDirect