Lithium Chlorides and Bromides as Promising Solid-State Chemistries for Fast Ion Conductors with Good Electrochemical Stability

Wang Shuo; Bai Qiang; Nolan Adelaide M.; Liu Yunsheng; Gong Sheng; Sun Qiang; Mo Yifei

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Lithium Chlorides and Bromides as Promising Solid-State Chemistries for Fast Ion Conductors with Good Electrochemical Stability

机译：氯化锂和溴化物作为具有良好电化学稳定性的快速离子导体的固态化学性

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Enabling all-solid-state Li-ion batteries requires solid electrolytes with high Li ionic conductivity and good electrochemical stability. Following recent experimental reports of Li3YCl6 and Li3YBr6 as promising new solid electrolytes, we used first principles computation to investigate the Li-ion diffusion, electrochemical stability, and interface stability of chloride and bromide materials and elucidated the origin of their high ionic conductivities and good electrochemical stabilities. Chloride and bromide chemistries intrinsically exhibit low migration energy barriers, wide electrochemical windows, and are not constrained to previous design principles for sulfide and oxide Li-ion conductors, allowing for much greater freedom in structure, chemistry, composition, and Li sublattice for developing fast Li-ion conductors. Our study highlights chloride and bromide chemistries as a promising new research direction for solid electrolytes with high ionic conductivity and good stability.

机译：启用全固态锂离子电池需要具有高Li离子电导率和良好电化学稳定性的固体电解质。遵循Li3YCL6和Li3YBR6的最新实验报告作为具有新的固体电解质，我们使用了第一种原理计算来研究氯化物和溴化物的锂离子扩散，电化学稳定性和界面稳定性，并阐明了其高离子导电性的起源和良好的电化学稳定性。氯化物和溴化物化学物质本质上表现出低迁移能屏障，宽电化学窗口，并且不受硫化物和氧化物锂离子导体的先前设计原理，允许更快速的结构，化学，组成和李子分离锂离子导体。我们的研究突出了氯化物和溴化物化学品作为具有高离子电导率和良好稳定性的固体电解质的有希望的新研究方向。

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来源
《Angewandte Chemie》 |2019年第24期|共5页
作者
Wang Shuo; Bai Qiang; Nolan Adelaide M.; Liu Yunsheng; Gong Sheng; Sun Qiang; Mo Yifei;
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作者单位

Peking Univ Coll Engn Dept Mat Sci &

Engn Beijing 100871 Peoples R China;

Univ Maryland Dept Mat Sci &

Engn College Pk MD 20742 USA;

Univ Maryland Dept Mat Sci &

Engn College Pk MD 20742 USA;

Univ Maryland Dept Mat Sci &

Engn College Pk MD 20742 USA;

Peking Univ Coll Engn Dept Mat Sci &

Engn Beijing 100871 Peoples R China;

Peking Univ Coll Engn Dept Mat Sci &

Engn Beijing 100871 Peoples R China;

Univ Maryland Dept Mat Sci &

Engn College Pk MD 20742 USA;

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原文格式 PDF
正文语种 eng
中图分类应用化学;
关键词
all-solid-state batteries; first principles computation; halides; Li-ion batteries; solid electrolytes;

机译：全固态电池;第一个原理计算;卤化物;锂离子电池;固体电解质;

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专利

1. Lithium Chlorides and Bromides as Promising Solid-State Chemistries for Fast Ion Conductors with Good Electrochemical Stability [J] . Wang Shuo, Bai Qiang, Nolan Adelaide M., Angewandte Chemie . 2019,第24期

机译：氯化锂和溴化物作为具有良好电化学稳定性的快速离子导体的固态化学性
2. SOLID-STATE ELECTROCHEMICAL CO2 SENSOR BY COUPLING LITHIUM ION CONDUCTOR (LI2CO3-LI3PO4-AL2O3) WITH OXIDE ION-ELECTRON MIXED CONDUCTOR (LA0.9SR0.1MNO3) [J] . Zhang YC., Asakura S., Mizusaki J., Solid state ionics . 1997,第3a4期

机译：锂离子导体（LI2CO3-LI3PO4-AL2O3）与氧化物离子电子混合导体（LA0.9SR0.1MNO3）耦合的固态电化学CO2传感器
3. SOLID-STATE ELECTROCHEMICAL CO2 SENSOR BY COUPLING LITHIUM ION CONDUCTOR (LI2CO3-LI3PO4-AL2O3) WITH OXIDE ION-ELECTRON MIXED CONDUCTOR (LA0.9SR0.1MNO3) [J] . Zhang YC., Asakura S., Mizusaki J., Solid state ionics . 1997,第3a4期

机译：锂离子导体（LI2CO3-LI3PO4-AL2O3）与氧化物离子电子混合导体（LA0.9SR0.1MNO3）耦合的固态电化学CO2传感器
4. SOLID-STATE ELECTROCHEMICAL CO_2 SENSOR BY COUPLING LITHIUM ION CONDUCTOR (Li_2CO_3-Li_2PO_4-Al_2O_3) WITH OXIDE ION-ELECTRON MIXED CONDUCTOR (La_(0.9)Sr_(0.1)MnO_3) [C] . Yi Can Zhang, Hidekazu Nariia, Junichiro Mizusaki, Chemical sensors . 1995

机译：锂离子导体（Li_2CO_3-Li_2PO_4-Al_2O_3）与氧化物离子电子混合导体（La_（0.9）Sr_（0.1）MnO_3）耦合的固态电化学CO_2传感器
5. Crystal chemistry, chemical stability, and electrochemical properties of layered oxide cathodes of lithium ion batteries. [D] . Choi, Jeh Won. 2006

机译：锂离子电池层状氧化物阴极的晶体化学，化学稳定性和电化学性质。
6. High-throughput design and optimization of fast lithium ion conductors by the combination of bond-valence method and density functional theory [O] . Ruijuan Xiao, Hong Li, Liquan Chen -1

机译：键价法与密度泛函理论相结合的高通量快速锂离子导体设计与优化
7. Lithium Chlorides and Bromides as Promising Solid‐State Chemistries for Fast Ion Conductors with Good Electrochemical Stability [O] . Shuo Wang, Qiang Bai, Adelaide M. Nolan, 2019

机译：氯化物和溴化物作为具有良好电化学稳定性的快速离子导体的固态化学品

Lithium Chlorides and Bromides as Promising Solid-State Chemistries for Fast Ion Conductors with Good Electrochemical Stability

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