Titlebook: Interface Ionics; For All-Solid-State Yasutoshi Iriyama,Koji Amezawa,Naoaki Yabuuchi Book 2024 Materials Research Society, under exclusive

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Trigger of the Highly Resistive Layer Formation at the Cathode-Electrolyte Interface in All-Solid-Stive layer formation process at the interface of a layered cathode: LiCoO. and a garnet-type solid-state electrolyte: Li.La.Zr.Ta.O., during the co-sintering process. The reaction between a delithiated Li.CoO. and Li.La.Zr.Ta.O. starts at 60 °C. The lithium chemical potential gap triggers the lithium

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Lithium Plating/Stripping Reactions at Oxide Solid Electrolyte Interfacestal anode in solid-state batteries. This chapter overviews fundamental studies on Li metal anodes in solid-state batteries with an emphasis on the contribution of mechanical work to deform current collectors to the overpotential and the interplay between the Li nucleation process and the reductive d

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Stable Interface Between Si-Negative Electrode and Oxide-Based Solid Electrolytean interface between an LLZT solid electrolyte and a silicon electrode. The Li. transfer process at the solid/solid interface was inherently faster than that for the solid/liquid interface using an electrolyte solution, while the interfacial resistance is usually high because the joint interface is

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Lithium Metal/Organic Solid Electrolyte Interfaces to Stabilize Li Plating/Stripping Reactione is hindered by the low Coulombic efficiency of Li plating/stripping reactions due to interfacial issues between Li metal and solid electrolyte, such as reductive decomposition of electrolytes, whisker-like Li growth, and poor interfacial contact between the solid materials. Among solid electrolyte