Buch, Englisch, 312 Seiten, Format (B × H): 202 mm x 248 mm, Gewicht: 768 g
Resources, Extraction, Batteries, and Recycling
Buch, Englisch, 312 Seiten, Format (B × H): 202 mm x 248 mm, Gewicht: 768 g
ISBN: 978-0-12-801417-2
Verlag: Elsevier Science Publishing Co Inc
Lithium Process Chemistry: Resources, Extraction, Batteries and Recycling presents, for the first time, the most recent developments and state-of-the-art of lithium production, lithium-ion batteries, and their recycling.
The book provides fundamental and theoretical knowledge on hydrometallurgy and electrochemistry in lithium-ion batteries, including terminology related to these two fields. It is of particular interest to electrochemists who usually have no knowledge in hydrometallurgy and hydrometallurgists not familiar with electrochemistry applied to Li-ion batteries.
It is also useful for both teachers and students, presenting an overview on Li production, Li-ion battery technologies, and lithium battery recycling processes that is accompanied by numerous graphical presentations of different battery systems and their electrochemical performances. The book represents the first time that hydrometallurgy and electrochemistry on lithium-ion batteries are assembled in one unique source.
Zielgruppe
<p>Chemical engineers, metallurgists, academic researchers in these areas</p> <p>Scientific library in universities and research institutes </p>
Autoren/Hrsg.
Fachgebiete
Weitere Infos & Material
1. Global Lithium Resources and Sustainability Issues
Patrice Christmann, Eric Gloaguen, Jean-François Labb_e, J_er_emie Melleton, Patrice Piantone
2. Fundamentals in Electrochemistry and Hydrometallurgy
Alexandre Chagnes
1. Fundamentals in Lithium-Ion Batteries
2. Fundamentals in Hydrometallurgy
3. Lithium Production Processes
Tam Tran, Van T. Luong
1. Introduction
2. Lithium Production Processes
3. New Project Development
4. Conclusions
4. Lithium Battery Technologies: From the Electrodes to the Batteries
Jolanta _Swiatowska, Philippe Barboux
1. Introduction
2. Battery Components and Electrode Limitations
3. Positive Electrode (Cathode) Materials
4. Negative Electrode (Anode) Materials
5. Separator and Current Collectors
6. Interface Chemistry in LiBs
5. Lithium Battery Technologies: Electrolytes
Alexandre Chagnes
1. Introduction
2. Liquid Electrolytes
3. Polymer Electrolytes
4. Anodic Stability of Liquid Electrolytes
5. Electrolyte Wettability
6. Conclusion
6. Perspectives in Lithium Batteries
Philippe Poizot, Franck Dolhem, Joël Gaubicher, St_even Renault
1. Introduction
2. Potential of Li-sulfur Batteries
3. Li-oxygen System for Ultrahigh-energy Density Batteries
4. Li-aqueous Batteries
5. Greener Opportunities Offered by Organic Batteries
7. Lithium Batteries Recycling
Christian Ekberg, Martina Petranikova
1. Introduction
2. Characterization of Spent LIBs Waste
3. Recycling of Spent Portable LiBs
4. Industrial Technologies for Spent LIBs Recycling
5. Conclusion
8. Life Cycle and Sustainability
Daniel Belchí Lorente, Guillaume Mandil, Lenka Svecova, Pierre-Xavier Thivel,
Peggy Zwolinski
1. Introduction
2. LCA Applied to LIBs "Concept, Method, and Key Results"
3. From Recycling Process Definition to Sustainable Industrial Solutions