Build a High‐Performance All‐Solid‐State Lithium Battery through Introducing Competitive Coordination Induction Effect in Polymer‐Based Electrolyte

Polymer‐inorganic composite electrolytes (PICE) have attracted tremendous attention in all‐solid‐state lithium batteries (ASSLBs) due to facile processability. However, the poor Li+ conductivity at room temperature (RT) and interfacial instability severely hamper the practical application. Herein, w...

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Published in:Angewandte Chemie International Edition 2024-04, Vol.63 (16), p.e202400960-n/a
Main Authors: Wang, Tenghui, Chen, Butian, Liu, Chong, Li, Taiguang, Liu, Xiangfeng
Format: Article
Language:English
Subjects:
All-Solid-State Lithium Battery
Cesium
Competition
Competitive Coordination Induction Effect
Composite materials
Conductivity
Coordination
Electrochemical Performance
Electrochemistry
Electrolytes
Electrostatic shielding
Interface stability
Interfacial Chemistry
Ion currents
Lithium
Lithium batteries
Lithium oxides
Polymer-Inorganic Composite Solid Electrolyte
Polymers
Room temperature
Solid electrolytes
Wetting agents
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Summary:Polymer‐inorganic composite electrolytes (PICE) have attracted tremendous attention in all‐solid‐state lithium batteries (ASSLBs) due to facile processability. However, the poor Li+ conductivity at room temperature (RT) and interfacial instability severely hamper the practical application. Herein, we propose a concept of competitive coordination induction effects (CCIE) and reveal the essential correlation between the local coordination structure and the interfacial chemistry in PEO‐based PICE. CCIE introduction greatly enhances the ionic conductivity and electrochemical performances of ASSLBs at 30 °C. Owing to the competitive coordination (Cs+…TFSI−…Li+, Cs+…C−O−C…Li+ and 2,4,6‐TFA…Li…TFSI−) from the competitive cation (Cs+ from CsPF6) and molecule (2,4,6‐TFA: 2,4,6‐trifluoroaniline), a multimodal weak coordination environment of Li+ is constructed enabling a high efficient Li+ migration at 30 °C (Li+ conductivity: 6.25×10−4 S cm−1; tLi+=0.61). Since Cs+ tends to be enriched at the interface, TFSI− and PF6− in situ form LiF‐Li3N‐Li2O‐Li2S enriched solid electrolyte interface with electrostatic shielding effects. The assembled ASSLBs without adding interfacial wetting agent exhibit outstanding rate capability (LiFePO4: 147.44 mAh g−1@1 C and 107.41mAhg−1@2 C) and cycling stability at 30 °C (LiFePO4:94.65 %@200cycles@0.5 C; LiNi0.5Co0.2Mn0.3O2: 94.31 %@200 cycles@0.3 C). This work proposes a concept of CCIE and reveals its mechanism in designing PICE with high ionic conductivity as well as high interfacial compatibility at near RT for high‐performance ASSLBs. We propose a new concept of competitive coordination induction effects (CCIE) and reveal the essential correlation between the local coordination structure and the interfacial chemistry in PEO‐based PICE. The intrinsic mechanism of CCIE and its effects on both the Li+ conductivity and the interfacial stability at RT were clarified. The assembled all‐solid‐state batteries without adding interfacial wetting agent exhibit outstanding rate capability and cycling performance at 30 °C.
ISSN:1433-7851
1521-3773
DOI:10.1002/anie.202400960