New Trends in Intercalation Compounds for Energy Storage - NATO Science Series II 2002 edition

Marc Notes: Includes bibliographical references and index / Proceedings of the NATO Advanced Study Institute on New Trends in Intercalation Compounds for Energy Storage, Sozopol, Bulgaria, 22 September-2 October 2001 / Avail. in paper (ISBN 1402005954) at EUR 85.00Brief Description: Proceedings of the NATO Advanced Study Institute, held in Sozopol, Bulgaria, 22 September-2 October, 2001Table of Contents: Preface. Acknowledgements. Part 1: Lectures. Intercalation compounds for energy storage; C. Julien, et al. Lithium intercalation compounds - The reliability of the rigid-band model; C. Julien. Overview of carbon anodes for lithium-ion batteries; K. Zaghib, K. Kinoshita. Electronic structure of various forms of solid state carbons - Graphite intercalation compounds; J. Conard. From intercalation compounds to inserted clusters e.g. Li in carbon superanodes for secondary batteries; J. Conard. Lithium NMR in lithium-carbon solid state compounds; J. Conard, P. Lauginie. Critical review of H/Carbon literature and ab-initio research for a chemical site between two coronenes; F. Marinelli, et al. Carbon-based negative electrodes of lithium-ion batteries obtained from residua of the petroleum industry; R. Alcantara, et al. Hydrogen in metals; J. Huot. Effects of composition in La/Ni-based intermetallic compounds used as negative electrodes in Ni-MH batteries; R. Baddour-Hadjean, et al. Lithium insertion compounds for energy storage; A. Manthiram. Chemical and structural stabilities of layered oxide cathodes; A. Manthiram. In situ preparation of composite electrodes: antimony alloys and compounds; R. Alcantara, et al. On the use of in-situ generated tin-based composite materials in lithium-ion cells; R. Alcantara, et al. Physical chemistry of lithium intercalation compounds; C. Julien. Lattice dynamics of manganese oxides and their intercalated compounds; C. Julien, M. Massot. Physical chemistry and electrochemistry of intercalation in disordered compounds; C. Julien, B. Yebka. Modifief host lattices for Li intercalation with improved electrochemical properties; J. P. Pereira-Ramos, et al. Surface science investigations of intercalation reactions with layered metaldichalcogenides; W. Jaegermann, D. Tonti. Conductive polymers and hybrid materials as insertion electrodes for energy storage applications; P. Gomez-Romero. An electrochemical point of view on the intercalation compounds; A. Momchilov. Manganese dioxides promising cathode materials for lithium batteries; B. Banov. Part 2: Seminars. Impedance of diffusion of inserted ions. Simple and advanced models; J. Bisquert. Dielectric relaxation spectroscopy for probing ion/network interactions in solids F. Henn, et al. Cations mobility and water adsorption in zeolites; G. Maurin, et al. Strategies to improve the cycling performance of lithium storage alloys; M. Wachtler, et al. Nanoscaled containers for hydrogen; I. D. Dragieva, et al. Nanocrystalline materials for lithium batteries; C. W. Kwon, et al. Study of fluorinated graphite intercalation compounds; I. P. Asanov, et al. Insertion of rare-earth metals into AgI-based compounds First evidence of disordering and strong modification of ss- and a-AgI crystal structures; A. L. Despotuli. Structural characterization of Mg treated LiCoO2 intercalation compounds; R. Stoyanova, et al. Electronic structure of oxygen in delitiated LiTMO2 studied by electron energy-loss spectrometry; J. Graetz, et al. Short-range Co/Mn ordering and electrochemical intercalation of Li into Li[Mn2-yCoy]O4 spinels, 0"