A lithium-ion battery comprises essentially three components: two intercalation compounds as positive and negative electrodes, separated by an ionic-electronic electrolyte. Each component is discussed in sufficient detail to give the practising engineer an understanding of the subject, providing guidance on the selection of suitable materials in actual applications. Each topic covered is written by an expert, reflecting many years of experience in research and applications. Each topic is provided with an extensive list of references, allowing easy access to further information. Readership: Research students and engineers seeking an expert review. Graduate courses in electrical drives can also be designed around the book by selecting sections for discussion. The coverage and treatment make the book indispensable for the lithium battery community.

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Preface. Acknowledgements. Part 1: Lectures. Design considerations for lithium batteries; C. Julien. Principles determining the potentials and capacities of electrochemical cells; R.A. Huggins. Binary electrodes under equilibrium or near-equilibrium conditions; R.A. Huggins. Better electrode materials for energy storage applications through chemistry; J.M. Tarascon. Carbon-lithium negative electrode for lithium ion batteries: main characteristics and features; R. Yazami. Reactivity and safety aspects of carbonaceous anodes used in lithium-ion batteries. Correlation of structural parameters and reactivity; G.A. Nazri, B. Yebka. Structure and electrochemistry of new lithium intercalation compounds prepared via low temperature techniques; J.P. Pereira-Ramos, et al. Structure and electrochemistry of doped LiMO2 (M=Ni, Co) cathode materials; C. Julien. New transition metal oxide electrodes for lithium batteries; A. Le Gal La Salle, et al. Electrochemical features of lithium batteries based on molybdenum-oxide compounds; C. Julien, B. Yebka. EXAFS: a structural probe for cathode materials in lithium ion batteries; M.S. Islam, et al. Atomistic computer modelling of oxide cathode materials for lithium ion batteries; M.S. Islam, B. Ammundsen. Local environment in 4-volt cathode materials for Li-ion batteries; C. Julien. Raman Spectra of anode and cathode materials; R. Aroca, et al. Advanced impendance techniques for lithium batteries study. Part I: experimental setup; Z. Stoynov. Advanced impedance techniques for lithium batteries study. Part II: data processing; Z. Stonoyv. Advanced impedance techniques for lithium batteries study. Part III: Four dimensional; Z. Stoynov. Advanced impedance techniques for lithium batteries study. PartIV: differential impedance analysis; Z. Stoynov. Litium microbatteries; C. Julien. Fundamental aspects of electrochemical, chemical and electrostatic potentials in lithium batteries; W. Weppner. Chemical stability aspects of high performance lithium batteries; W. Weppner. Kinetic aspects of high performance solid electrolytes and electrodes; W. Weppner. Solid state electrochemical methods for the characterization of the kinetics, thermodynamics and phase equilibria of lithium battery materials; W. Weppner. Part 2: Seminars. LiNi(M)O2 layered oxides: positive electrode materials for lithium batteries; A. Rougier, C. Delmas. New generation of 3-volt lithiated manganese oxide for high-performance lithium batteries; B. Banov, et al. Sol-gel synthesis and electrochemical characterization of polycrystalline powders and thin films of Li1+xV3O8; S.V. Pushko. Microstructure of Li1+xMn2-xMn2-xO4 cathode materials monitored by EPR of mn4+; E. Zhecheva, et al. EPR studies on the microstructure of LiNi1-yCoyO2 electrode materials for lithium-ion batteries; R. Stoyanova, et al. Mechanochemical synthesis of cathode materials for lithium batteries; N.V. Kosova. Electronic transport properties in LixCr0.11V2O5.16; J.C. Badot, et al. 7Li NMR in some lithium intercalation compounds. Taking advantage of electronic spins; M. Ménétrier. Single conductive polymer electrolytes: from pressure conductivity measurements to transport mechanism; O. Brylev, et al. Electrochemical and structural characterisation near the NiO2 composition; L. Croguennec, et al. Synthesis of o