Solid Electrolytes for Advanced Applications

This book highlights the state of the art in solid electrolytes, with particular emphasis on lithium garnets, electrolyte-electrode interfaces and all-solid-state batteries based on lithium garnets. Written by an international group of renowned experts, the book addresses how garnet-type solid electrolytes are contributing to the development of safe high energy density Li batteries. Unlike the flammable organic liquid electrolyte used in existing rechargeable Li batteries, garnet-type solid electrolytes are intrinsically chemically stable in contact with metallic lithium and potential positive electrodes, while offering reasonable Li conductivity. The book's respective chapters cover a broad spectrum of topics related to solid electrolytes, including interfacial engineering to resolve the electrolyte-electrode interfaces, the latest developments in the processing of thin and ultrathin lithium garnet membranes, and fabrication strategies for the high-performance solid-state batteries.This highly informative and intriguing book will appeal to postgraduate students and researchers at academic and industrial laboratories with an interest in the advancement of high energy-density lithium metal batteries

Introduces readers to the state of the art in solid electrolytes for rechargeable Li batteries Brings together work from leading international researchers Supports further research through a comprehensive bibliographies at the end of each chapter

Autorentext

Dr. Ramaswamy Murugan is Professor, Department of Physics, Pondicherry University, India. He received his Ph.D. in Physics from Pondicherry University, India in 1994. He was at University of Kiel, Germany as Guest researcher during 2005-2007. He was a visiting scientist at Shizuoka University Japan (2009), University of Texas Austin USA (2011) and Nagoya University, Japan (2013). His research focuses on the design, synthesis and characterization of functional materials in particular for applications in energy storage devices. His major contribution is the invention of zirconium containing lithium garnet oxide as electrolyte for the all solid state lithium battery.
Prof. Dr. Werner Weppner is a longtime and highly recognized expert in the field of solid state electrochemistry since his doctorate at Dortmund University followed by a fruitful postdoctoral period at Stanford University, where he became involved in lithium battery electrodes and new solid electrolytes. He then built up his solid state electrochemistry group at the new Max-Planck Institute for Solid State Research at Stuttgart and became a lecturer at Stuttgart University. In 1993 he took a Professorship and Chair for Solid State Ionics at the new Faculty of Engineering at the University of Kiel. His work covers a wide range of aspects of fast ion transport in solids from fundamental understanding, experimental techniques, materials characterization, development of new materials and principles with special attention to practical applications in lithium batteries, solid oxide fuel cells, sensors and electrochromic devices. The accumulated experience has final led to the discovery of the family of garnet type solid electrolytes. He is also involved in a large variety of academic and professional activities, among many others scientific conferences for the promotion of the field and Chief Editorship of the journal Ionics published by Springer.

Inhalt
From the content: Solid Electrolytes: Thermodynamic Approach.- Solid Electrolytes: Structural Approach.- Crystal Structure Analysis: Garnets.- Air Stability of LLZO Electrolytes.- Influence of Strain on Garnet Type Electrolytes.- Thin Film Deposition of Garnet Type Electolytes.- Ultrathin Garnet Type Electrolytes.-Nanostructured Garnet Electrolytes.- Sintering Additives for Garnet Type Electrolytes.- Composite PEO/Garnet Electrolyte.- Composite Tetragonal LLZO Based Electrolytes.- Zero-Strain Insertion Materials for All-Solid-State Li-Ion Batteries.- Air Cathodes for Alkaline Metal Air Batteries.- Vanadate Glass-Ceramics Cathode.- Interfacial Engineering of Lithium Metal Batteries Based on Garnets.