Reinforced cathode-garnet interface for high-capacity all-solid-state batteries

Materials Futures Pub Date : 2022-11-08 DOI:10.1088/2752-5724/aca110

Chenxi Zheng, Shijun Tang, Fangmei Wen, Jinxue Peng, Wu Yang, Zhongwei Lv, Yongmin Wu, Weiping Tang, Z. Gong, Yong Yang

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引用次数: 12

Abstract

Garnet-type solid-state electrolytes (SSEs) are particularly attractive in the construction of all-solid-state lithium (Li) batteries due to their high ionic conductivity, wide electrochemical window and remarkable (electro)chemical stability. However, the intractable issues of poor cathode/garnet interface and general low cathode loading hinder their practical application. Herein, we demonstrate the construction of a reinforced cathode/garnet interface by spark plasma sintering, via co-sintering Li6.5La3Zr1.5Ta0.5O12 (LLZTO) electrolyte powder and LiCoO2/LLZTO composite cathode powder directly into a dense dual-layer with 5 wt% Li3BO3 as sintering additive. The bulk composite cathode with LiCoO2/LLZTO cross-linked structure is firmly welded to the LLZTO layer, which optimizes both Li-ion and electron transport. Therefore, the one-step integrated sintering process implements an ultra-low cathode/garnet interfacial resistance of 3.9 Ω cm2 (100 °C) and a high cathode loading up to 2.02 mAh cm−2. Moreover, the Li3BO3 reinforced LiCoO2/LLZTO interface also effectively mitigates the strain/stress of LiCoO2, which facilitates the achieving of superior cycling stability. The bulk-type Li|LLZTO|LiCoO2-LLZTO full cell with areal capacity of 0.73 mAh cm−2 delivers capacity retention of 81.7% after 50 cycles at 100 μA cm−2. Furthermore, we reveal that non-uniform Li plating/stripping leads to the formation of gaps and finally results in the separation of Li and LLZTO electrolyte during long-term cycling, which becomes the dominant capacity decay mechanism in high-capacity full cells. This work provides insight into the degradation of Li/SSE interface and a strategy to radically improve the electrochemical performance of garnet-based all-solid-state Li batteries.

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用于高容量全固态电池的强化阴极-石榴石界面

石榴石型固态电解质(sse)由于其高离子电导率、宽电化学窗口和显著的(电)化学稳定性，在全固态锂(Li)电池的构建中尤其具有吸引力。然而，阴极/石榴石界面差和阴极负载普遍较低的棘手问题阻碍了其实际应用。本文采用火花等离子烧结的方法，将Li6.5La3Zr1.5Ta0.5O12 (LLZTO)电解质粉末和LiCoO2/LLZTO复合阴极粉末直接共烧结成致密的双层结构，并添加5 wt%的Li3BO3作为烧结添加剂，构建了增强阴极/石榴石界面。将具有LiCoO2/LLZTO交联结构的块状复合阴极牢固地焊接在LLZTO层上，优化了锂离子和电子的传递。因此，一步集成烧结工艺实现了3.9 Ω cm2(100°C)的超低阴极/石榴石界面电阻和高达2.02 mAh cm - 2的高阴极负载。此外，Li3BO3增强的LiCoO2/LLZTO界面也有效地减轻了LiCoO2的应变/应力，有利于实现优异的循环稳定性。体积型Li|LLZTO|LiCoO2-LLZTO全电池面积容量为0.73 mAh cm−2，在100 μA cm−2下循环50次后容量保持率为81.7%。此外，我们还发现，在长期循环过程中，不均匀的Li镀/剥离导致间隙的形成，最终导致Li和LLZTO电解质的分离，这成为高容量满电池中主要的容量衰减机制。这项工作为Li/SSE界面的退化提供了见解，并为从根本上提高石榴石基全固态锂电池的电化学性能提供了策略。

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

Materials Futures

CiteScore

7.40

自引率

0.00%

发文量