Titlebook: Electrolytes for Lithium and Lithium-Ion Batteries; T. Richard Jow,Kang Xu,Makoto Ue Book 2014 Springer Science+Business Media New York 20

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Nonaqueous Electrolytes: Advances in Lithium Salts,ialization of Li-ion batteries with a graphite anode, LiPF. became the dominant salt for lithium battery electrolytes. But the advent of new electrodes/cell chemistries (e.g., Si alloy anodes, high-voltage cathodes, Li-air, Li-S), as well as the need for exceptional battery safety, higher/lower temp

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Nonaqueous Electrolytes and Advances in Additives,icult to learn rapidly and systematically about this subject from past to present. Today, it is totally impossible to satisfy all the required battery properties by single additive in the electrolyte, and the mainstream of electrolyte development is equal to “quest for multiple combinations of addit

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Recent Advances in Ionic Liquids for Lithium Secondary Batteries,ed volatility, and a relatively high ionic conductivity at ambient temperature. The existence of ILs has become especially popular in various fields during the past two decades due to the discovery of moisture-insensitive ILs based on perfluoroanions—such as tetrafluoroborate [BF.]., and bis(trifluo

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,Tools and Methodologies for the Characterization of Electrode–Electrolyte Interfaces, and Li-ion batteries. Such progress would not have been possible without a parallel development in experimental techniques that are capable of interrogating these interfaces with ever increasing level of chemical and spatial resolutions. The purpose of this chapter is to provide an overview of thes

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Molecular Modeling of Electrolytes,pter discusses applications of quantum chemistry methods to determine electrolyte oxidative stability and oxidation-induced decomposition reactions. A link between the oxidation stability of model electrolyte clusters and the kinetics of oxidation reactions is established and compared with the resul

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