Synergistic Li6PS5Cl@Li3OCl composite electrolyte for high-performance all-solid-state lithium batteries

IF 10.7 1区工程技术 Q1 CHEMISTRY, PHYSICAL

Green Energy & Environment Pub Date : 2024-07-04 DOI:10.1016/j.gee.2024.07.001

Yuzhe Zhang, Haolong Chang, Aiguo Han, Shijie Xu, Xinyu Wang, Shunjin Yang, Xiaohu Hu, Yujiang Sun, Xiao Sun, Xing Chen, Yongan Yang

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Abstract

LiPSCl is a highly wanted sulfide-solid-electrolyte (SSE) for developing all-solid-state lithium batteries, due to its high ionic conductivity, good processability and abundant compositional elements. However, its cyclability is poor because of harmful side reactions at the LiPSCl/Li interface and growth of lithium dendrites inside LiPSCl phase. Herein, we report a simple interface-engineering remedy to boost the electrochemical performance of LiPSCl, by coating its surface with a Li-compatible electrolyte LiOCl having low electronic conductivity. The obtained LiPSCl@LiOCl core@shell structure exhibits a synergistic effect. Consequently, compared with the bare LiPSCl, this composite electrolyte exhibits great performance improvements: 1) In Li|electrolyte|Li symmetric cells, the critical current density at 30 °C gets increased from 0.6 mA cm to 1.6 mA cm, and the lifetime gets prolonged from 320 h to 1400 h at the cycling current of 0.2 mA cm or from 6 h to 900 h at the cycling current of 0.5 mA cm; 2) In Li|electrolyte|NCM721 full cells running at 30 °C, the cycling capacity at 0.2 C (or 0.5 C) gets enhanced by 20% (or from unfeasible to be feasible) for 100 cycles and the rate capability reaches up to 2 C from 0.2 C; and in full cells running at 60 °C, the cycling capacity is increased by 7% at 0.2 C and the rate capability is enhanced to 3.0 C from 0.5 C. The experimental studies and theoretical computations show that the performance enhancements are due to the confined electron penetration and suppressed lithium dendrites growth at the LiPSCl@LiOCl interface.

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用于高性能全固态锂电池的 Li6PS5Cl@Li3OCl 复合电解质的协同作用

由于具有高离子导电性、良好的可加工性和丰富的组成元素，LiPSCl 是开发全固态锂电池的理想硫化物-固体电解质（SSE）。然而，由于 LiPSCl/Li 界面的有害副反应以及 LiPSCl 相内锂枝晶的生长，其循环性较差。在此，我们报告了一种简单的界面工程补救方法，即在 LiPSCl 表面涂覆具有低电子传导性的锂兼容电解质 LiOCl，以提高其电化学性能。所获得的 LiPSCl@LiOCl 核@壳结构具有协同效应。因此，与裸 LiPSCl 相比，这种复合电解质的性能有了很大提高：1) 在锂|电解质|锂对称电池中，30 °C 时的临界电流密度从 0.6 mA cm 提高到 1.6 mA cm，循环电流为 0.2 mA cm 时的寿命从 320 h 延长到 1400 h，循环电流为 0.5 mA cm 时的寿命从 6 h 延长到 900 h；2) 在 30 °C 下运行的锂|电解质|NCM721 全电池中，0.2 C（或 0.实验研究和理论计算表明，性能的提高是由于在 LiPSCl@LiOCl 界面限制了电子的穿透并抑制了锂枝晶的生长。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Green Energy & Environment Energy-Renewable Energy, Sustainability and the Environment

CiteScore

16.80

自引率

3.80%

发文量

332

审稿时长

12 days

期刊介绍： Green Energy & Environment (GEE) is an internationally recognized journal that undergoes a rigorous peer-review process. It focuses on interdisciplinary research related to green energy and the environment, covering a wide range of topics including biofuel and bioenergy, energy storage and networks, catalysis for sustainable processes, and materials for energy and the environment. GEE has a broad scope and encourages the submission of original and innovative research in both fundamental and engineering fields. Additionally, GEE serves as a platform for discussions, summaries, reviews, and previews of the impact of green energy on the eco-environment.

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