Progress and perspectives on halide lithium conductors for all-solid-state lithium batteries

Halide solid-state electrolytes (SSEs) with high room-temperature ionic conductivity (>10 −3 S cm −1 ), wide electrochemical windows, and good compatibility toward oxide cathode materials have achieved impressive progress and attracted significant attention for application in all-solid-state lith...

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Published inEnergy & environmental science Vol. 13; no. 5; pp. 1429 - 1461
Main Authors Li, Xiaona, Liang, Jianwen, Yang, Xiaofei, Adair, Keegan R, Wang, Changhong, Zhao, Feipeng, Sun, Xueliang
Format Journal Article
LanguageEnglish
Published Cambridge Royal Society of Chemistry 2020
Subjects
Conductivity
Conductors
Electrochemistry
Electrode materials
Electrolytes
Energy storage
High temperature
Interface stability
Ion currents
Liquid phases
Lithium
Lithium batteries
Molten salt electrolytes
Room temperature
Solid electrolytes
Solid state
Synthesis
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Abstract Halide solid-state electrolytes (SSEs) with high room-temperature ionic conductivity (>10 −3 S cm −1 ), wide electrochemical windows, and good compatibility toward oxide cathode materials have achieved impressive progress and attracted significant attention for application in all-solid-state lithium batteries (ASSLBs). This review presents an overview of halide SSEs, including their development, structure, ionic conductivity, chemical stability, and current limitations. Firstly, we give a brief overview of the historical development of halide-based SSEs, followed by an introduction to the different types of halide SSEs. From a practical point of view, the synthesis methods, especially scalable liquid-phase synthesis, are intensively discussed. Then, the associated stability issues involving basic structure stability, air/humidity stability, and electrochemical stability (electrolyte/SSE interface and electrochemical stability window) are also discussed in detail. Comprehensive coverage and thorough understanding of the properties of halide SSEs are provided and it is expected to help guide the development of future SSEs towards ASSLBs for energy storage applications. This review focuses on fundamental understanding, various synthesis routes, chemical/electrochemical stability of halide-based lithium superionic conductors, and their potential applications in energy storage as well as related challenges.
AbstractList Halide solid-state electrolytes (SSEs) with high room-temperature ionic conductivity (>10−3 S cm−1), wide electrochemical windows, and good compatibility toward oxide cathode materials have achieved impressive progress and attracted significant attention for application in all-solid-state lithium batteries (ASSLBs). This review presents an overview of halide SSEs, including their development, structure, ionic conductivity, chemical stability, and current limitations. Firstly, we give a brief overview of the historical development of halide-based SSEs, followed by an introduction to the different types of halide SSEs. From a practical point of view, the synthesis methods, especially scalable liquid-phase synthesis, are intensively discussed. Then, the associated stability issues involving basic structure stability, air/humidity stability, and electrochemical stability (electrolyte/SSE interface and electrochemical stability window) are also discussed in detail. Comprehensive coverage and thorough understanding of the properties of halide SSEs are provided and it is expected to help guide the development of future SSEs towards ASSLBs for energy storage applications.
Halide solid-state electrolytes (SSEs) with high room-temperature ionic conductivity (>10 −3 S cm −1 ), wide electrochemical windows, and good compatibility toward oxide cathode materials have achieved impressive progress and attracted significant attention for application in all-solid-state lithium batteries (ASSLBs). This review presents an overview of halide SSEs, including their development, structure, ionic conductivity, chemical stability, and current limitations. Firstly, we give a brief overview of the historical development of halide-based SSEs, followed by an introduction to the different types of halide SSEs. From a practical point of view, the synthesis methods, especially scalable liquid-phase synthesis, are intensively discussed. Then, the associated stability issues involving basic structure stability, air/humidity stability, and electrochemical stability (electrolyte/SSE interface and electrochemical stability window) are also discussed in detail. Comprehensive coverage and thorough understanding of the properties of halide SSEs are provided and it is expected to help guide the development of future SSEs towards ASSLBs for energy storage applications. This review focuses on fundamental understanding, various synthesis routes, chemical/electrochemical stability of halide-based lithium superionic conductors, and their potential applications in energy storage as well as related challenges.
Halide solid-state electrolytes (SSEs) with high room-temperature ionic conductivity (>10 −3 S cm −1 ), wide electrochemical windows, and good compatibility toward oxide cathode materials have achieved impressive progress and attracted significant attention for application in all-solid-state lithium batteries (ASSLBs). This review presents an overview of halide SSEs, including their development, structure, ionic conductivity, chemical stability, and current limitations. Firstly, we give a brief overview of the historical development of halide-based SSEs, followed by an introduction to the different types of halide SSEs. From a practical point of view, the synthesis methods, especially scalable liquid-phase synthesis, are intensively discussed. Then, the associated stability issues involving basic structure stability, air/humidity stability, and electrochemical stability (electrolyte/SSE interface and electrochemical stability window) are also discussed in detail. Comprehensive coverage and thorough understanding of the properties of halide SSEs are provided and it is expected to help guide the development of future SSEs towards ASSLBs for energy storage applications.
Author Liang, Jianwen
Wang, Changhong
Yang, Xiaofei
Zhao, Feipeng
Adair, Keegan R
Li, Xiaona
Sun, Xueliang
AuthorAffiliation Department of Mechanical and Materials Engineering
University of Western Ontario
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Notes Xiaona Li is a Mitacs Postdoc Fellow in Prof. Xueliang (Andy) Sun's Group at the University of Western Ontario (Western Univerisity), Canada. She received her BS degree in materials chemistry in 2011 from Sichuan University and PhD degree in inorganic chemistry in 2015 under the supervision of Prof. Dr Yitai Qian on the study of electrode materials synthesis for lithium batteries from the University of Science and Technology of China. She joined Prof. Sun's group in 2017 and her current research interests focus on the synthesis of sulfide and halide solid electrolytes as well as all-solid-state lithium batteries.
Keegan Adair received his BSc in chemistry from the University of British Columbia in 2016. He is currently a PhD candidate in Prof. Xueliang (Andy) Sun's Nanomaterials and Energy Group at the University of Western Ontario, Canada. Keegan has previous experience in the battery industry through internships at companies including E-One Moli Energy and General Motors R&D. His research interests include the design of nanomaterials for lithium metal batteries and nanoscale interfacial coatings for battery applications.
Prof. Xueliang (Andy) Sun is a Canada Research Chair in Development of Nanomaterials for Clean Energy, Fellow of the Royal Society of Canada and Canadian Academy of Engineering and Full Professor at the University of Western Ontario, Canada. Dr Sun received his PhD in materials chemistry in 1999 from the University of Manchester, UK, which he followed up by working as a postdoctoral fellow at the University of British Columbia, Canada and as a Research Associate at L'Institut National de la Recherche Scientifique (INRS), Canada. His current research interests are focused on advanced materials for electrochemical energy storage and conversion, including solid-state batteries, interface and solid-state electrolytes and electrocatalysts.
Xiaofei Yang is currently a postdoctoral associate in Prof. Xueliang (Andy) Sun's Nanomaterials and Energy Group. He received his BS degree in Chemical Engineering from Anhui University, China, in 2013 and PhD degree from Dalian Institute of Chemical Physics, Chinese Academy of Sciences, China, in 2018 under the supervision of Prof. Huamin Zhang. His research interests focus on Li-S batteries, all-solid-state Li-ion and Li-S batteries and battery interface studies via synchrotron X-ray characterization.
10.1039/c9ee03828k
Changhong Wang is currently a PhD candidate in Prof. Xueliang (Andy) Sun's Group at the University of Western Ontario, Canada. He got his BS in applied chemistry from the University of Science and Technology of Anhui in 2011 and obtained his MS degree in materials engineering from the University of Science and Technology of China in 2014. After graduation, he also served as a research assistant at Singapore University of Technology and Design from 2014 to 2016. Currently, his research interests include solid-state sulfide electrolytes and all-solid-state LIBs and Li-S batteries.
Feipeng Zhao is currently a PhD candidate in Prof. Xueliang (Andy) Sun's Group at the University of Western Ontario, Canada. He received his BS degree and MS degree in Materials Science from Soochow University in 2014 and 2017, respectively. Currently, he is working on the synthesis and characterization of sulfide electrolytes, and development of high-performance solid-state Li metal and Na metal batteries.
Electronic supplementary information (ESI) available. See DOI
Jianwen Liang is a Mitacs Postdoc Fellow in Prof. Xueliang (Andy) Sun's Group at the University of Western Ontario (Western Univerisity), Canada. He received his B.S. degree in Chemical Engineering and Technology from Wuyi University in 2010 and PhD degree in inorganic chemistry from the University of Science and Technology of China in 2015. He joined Prof. Sun's group in 2017 and his current research interests include sulfide and halide solid electrolytes as well as all-solid-state Li/Li-ion batteries.
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PublicationPlace Cambridge
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PublicationTitle Energy & environmental science
PublicationYear 2020
Publisher Royal Society of Chemistry
Publisher_xml – name: Royal Society of Chemistry
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Snippet Halide solid-state electrolytes (SSEs) with high room-temperature ionic conductivity (>10 −3 S cm −1 ), wide electrochemical windows, and good compatibility...
Halide solid-state electrolytes (SSEs) with high room-temperature ionic conductivity (>10−3 S cm−1), wide electrochemical windows, and good compatibility...
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SubjectTerms Conductivity
Conductors
Electrochemistry
Electrode materials
Electrolytes
Energy storage
High temperature
Interface stability
Ion currents
Liquid phases
Lithium
Lithium batteries
Molten salt electrolytes
Room temperature
Solid electrolytes
Solid state
Synthesis
Title Progress and perspectives on halide lithium conductors for all-solid-state lithium batteries
URI https://www.proquest.com/docview/2404546427
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