He Xuewei, Zhu Zhiwei, Wen Guojiang, Lv Shanshan, Yang Sifan, Hu Ting, Cao Zheng, Ji Yuan, Fu Xuewei, Yang Wei, Wang Yu
College of Polymer Science and Engineering, State Key Laboratory of Polymer Materials Engineering, Sichuan University, Chengdu, Sichuan, 610065, China.
Adv Mater. 2024 Apr;36(16):e2307599. doi: 10.1002/adma.202307599. Epub 2023 Dec 14.
Advanced solid electrolytes with strong adhesion to other components are the key for the successes of solid-state batteries. Unfortunately, traditional solid electrolytes have to work under high compression to maintain the contact inside owing to their poor adhesion. Here, a concept of high-entropy tape electrolyte (HETE) is proposed to simultaneously achieve tape-like adhesion, liquid-like ion conduction, and separator-like mechanical properties. This HETE is designed with adhesive skin layer on both sides and robust skeleton layer in the middle. The significant properties of the three layers are enabled by high-entropy microstructures which are realized by harnessing polymer-ion interactions. As a result, the HETE shows high ionic conductivity (3.50 ± 0.53 × 10 S cm at room temperature), good mechanical properties (toughness 11.28 ± 1.12 MJ m, strength 8.18 ± 0.28 MPa), and importantly, tape-like adhesion (interfacial toughness 231.6 ± 9.6 J m). Moreover, a compression-free solid-state tape battery is finally demonstrated by adhesion-based assembling, which shows good interfacial and electrochemical stability even under harsh mechanical conditions, such as twisting and bending. The concept of HETE and compression-free solid-state tape batteries may bring promising solutions and inspiration to conquer the interface challenges in solid-state batteries and their manufacturing.
与其他组件具有强附着力的先进固体电解质是固态电池成功的关键。不幸的是,传统固体电解质由于附着力差,必须在高压力下工作以维持内部接触。在此,提出了一种高熵胶带电解质(HETE)的概念,以同时实现胶带状附着力、液体状离子传导和隔板状机械性能。这种HETE设计为两侧有粘性表层,中间有坚固的骨架层。这三层的显著性能由通过利用聚合物 - 离子相互作用实现的高熵微观结构赋予。结果,HETE表现出高离子电导率(室温下为3.50±0.53×10 S cm)、良好的机械性能(韧性为11.28±1.12 MJ m,强度为8.18±0.28 MPa),重要的是,具有胶带状附着力(界面韧性为231.6±9.6 J m)。此外,最终通过基于附着力的组装展示了一种无压缩的固态胶带电池,即使在扭曲和弯曲等恶劣机械条件下,该电池也表现出良好的界面和电化学稳定性。HETE和无压缩固态胶带电池的概念可能为克服固态电池及其制造中的界面挑战带来有前景的解决方案和灵感。
