{"title":"低含量溴取代加速全固态电池氯电解质中Li+的传导","authors":"Qian Zhao*, , , Weizong Wang, , , Cheng Ruan, , , Zhengping Ding, , and , Yurong Ren*, ","doi":"10.1021/acsaem.5c02440","DOIUrl":null,"url":null,"abstract":"<p >Chloride-based solid-state electrolytes (SSEs) have attracted significant attention due to their favorable combination of ionic conductivity and electrochemical stability. However, chloride SSEs exhibit lower ionic conductivity than sulfides and liquid electrolytes, along with Li metal instability, hindering their high-rate all-solid-state battery (ASSB) applications. Previous studies have emphasized a cation substitution strategy, particularly high-entropy design, to enhance ionic conductivity, while anion substitution remains an underexplored yet promising alternative. Herein, through low-content Br substitution, Li<sub>3</sub>InCl<sub>5.9</sub>Br<sub>0.1</sub> is synthesized via mechanical ball milling and achieves a room-temperature ionic conductivity of 1.30 mS cm<sup>–1</sup>, which represents a 48% enhancement over pristine Li<sub>3</sub>InCl<sub>6</sub> (0.88 mS cm<sup>–1</sup>). Combined experimental and theoretical analyses reveal that the enhanced ionic conductivity stems from moderate local lattice distortion and optimized Li–Cl/Br bond lengths that facilitate Li<sup>+</sup> conduction. The assembled LiCoO<sub>2</sub>|Li<sub>3</sub>InCl<sub>5.9</sub>Br<sub>0.1</sub>|Li<sub>6</sub>PS<sub>5</sub>Cl|Li–In ASSBs significantly demonstrate 81.89% capacity retention after 100 cycles at 0.2C (vs 70.55% for ASSBs with pristine Li<sub>3</sub>InCl<sub>6</sub>), along with improved rate performance. This work provides a reliable strategy of low-content Br<sup>–</sup> substitution to develop advanced chloride SSEs for application in ASSBs.</p>","PeriodicalId":4,"journal":{"name":"ACS Applied Energy Materials","volume":"8 19","pages":"14671–14678"},"PeriodicalIF":5.5000,"publicationDate":"2025-10-02","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Low-Content Bromine Substitution Accelerates Li+ Conduction in Chloride Electrolytes for All-Solid-State Batteries\",\"authors\":\"Qian Zhao*, , , Weizong Wang, , , Cheng Ruan, , , Zhengping Ding, , and , Yurong Ren*, \",\"doi\":\"10.1021/acsaem.5c02440\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p >Chloride-based solid-state electrolytes (SSEs) have attracted significant attention due to their favorable combination of ionic conductivity and electrochemical stability. However, chloride SSEs exhibit lower ionic conductivity than sulfides and liquid electrolytes, along with Li metal instability, hindering their high-rate all-solid-state battery (ASSB) applications. Previous studies have emphasized a cation substitution strategy, particularly high-entropy design, to enhance ionic conductivity, while anion substitution remains an underexplored yet promising alternative. Herein, through low-content Br substitution, Li<sub>3</sub>InCl<sub>5.9</sub>Br<sub>0.1</sub> is synthesized via mechanical ball milling and achieves a room-temperature ionic conductivity of 1.30 mS cm<sup>–1</sup>, which represents a 48% enhancement over pristine Li<sub>3</sub>InCl<sub>6</sub> (0.88 mS cm<sup>–1</sup>). Combined experimental and theoretical analyses reveal that the enhanced ionic conductivity stems from moderate local lattice distortion and optimized Li–Cl/Br bond lengths that facilitate Li<sup>+</sup> conduction. The assembled LiCoO<sub>2</sub>|Li<sub>3</sub>InCl<sub>5.9</sub>Br<sub>0.1</sub>|Li<sub>6</sub>PS<sub>5</sub>Cl|Li–In ASSBs significantly demonstrate 81.89% capacity retention after 100 cycles at 0.2C (vs 70.55% for ASSBs with pristine Li<sub>3</sub>InCl<sub>6</sub>), along with improved rate performance. 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引用次数: 0
摘要
氯基固态电解质由于其良好的离子电导率和电化学稳定性而受到广泛关注。然而,与硫化物和液体电解质相比,氯化物sse表现出较低的离子电导率,以及锂金属的不稳定性,阻碍了它们在高倍率全固态电池(ASSB)中的应用。先前的研究强调了阳离子替代策略,特别是高熵设计,以提高离子电导率,而阴离子替代仍然是一个未被充分探索但有希望的替代方案。通过低含量的Br取代,通过机械球磨合成了Li3InCl5.9Br0.1,室温离子电导率为1.30 mS cm-1,比原始Li3InCl6 (0.88 mS cm-1)提高了48%。结合实验和理论分析表明,离子电导率的增强源于适度的局部晶格畸变和优化的Li - cl /Br键长度,有利于Li+的传导。组装的LiCoO2|Li3InCl5.9Br0.1|Li6PS5Cl| Li-In assb在0.2C下进行100次循环后,其容量保持率显著达到81.89%(与原始Li3InCl6 assb相比为70.55%),同时提高了倍率性能。本工作为开发应用于assb的先进氯化物sss提供了一种可靠的低含量Br替代策略。
Low-Content Bromine Substitution Accelerates Li+ Conduction in Chloride Electrolytes for All-Solid-State Batteries
Chloride-based solid-state electrolytes (SSEs) have attracted significant attention due to their favorable combination of ionic conductivity and electrochemical stability. However, chloride SSEs exhibit lower ionic conductivity than sulfides and liquid electrolytes, along with Li metal instability, hindering their high-rate all-solid-state battery (ASSB) applications. Previous studies have emphasized a cation substitution strategy, particularly high-entropy design, to enhance ionic conductivity, while anion substitution remains an underexplored yet promising alternative. Herein, through low-content Br substitution, Li3InCl5.9Br0.1 is synthesized via mechanical ball milling and achieves a room-temperature ionic conductivity of 1.30 mS cm–1, which represents a 48% enhancement over pristine Li3InCl6 (0.88 mS cm–1). Combined experimental and theoretical analyses reveal that the enhanced ionic conductivity stems from moderate local lattice distortion and optimized Li–Cl/Br bond lengths that facilitate Li+ conduction. The assembled LiCoO2|Li3InCl5.9Br0.1|Li6PS5Cl|Li–In ASSBs significantly demonstrate 81.89% capacity retention after 100 cycles at 0.2C (vs 70.55% for ASSBs with pristine Li3InCl6), along with improved rate performance. This work provides a reliable strategy of low-content Br– substitution to develop advanced chloride SSEs for application in ASSBs.
期刊介绍:
ACS Applied Energy Materials is an interdisciplinary journal publishing original research covering all aspects of materials, engineering, chemistry, physics and biology relevant to energy conversion and storage. The journal is devoted to reports of new and original experimental and theoretical research of an applied nature that integrate knowledge in the areas of materials, engineering, physics, bioscience, and chemistry into important energy applications.
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