原位 Li2O-大气辅助无溶剂路线制备高导电性 Li7La3Zr2O12 固体电解质

Jiawen Tang, Yongjiang Zhou, Xiaoyi Li, Xiao Huang, Wei Tang, Bingbing Tian
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摘要

固态电池具有提高能量密度和安全性的潜力,因此备受关注。石榴石型 Li7La3Zr2O12(LLZO)陶瓷电解质是最有前途的固体电解质之一,因为它具有高导电性,而且易于在环境空气中制造。由于气-液-固烧结机理复杂,因此很难制备出性能优异、一致性高的 LLZO。本研究开发了一种原位 Li2O-大气辅助无溶剂路线来制备 LLZO 陶瓷。首先,应用富锂添加剂 Li6Zr2O7(LiZO)在晶界原位提供 Li2O 气氛,其分解产物(Li2ZrO3)在晶界之间架起桥梁。其次,比较了干法和湿法工艺对煅烧粉末和烧结陶瓷的结晶度、表面污染和粒度的影响。第三,通过分析晶界组成和陶瓷微观结构的演变,详细研究了干法和湿法工艺以及富锂添加剂 LiZO 对陶瓷烧结过程的影响,以阐明烧结行为和机制。最后,在 1,300 °C × 1 min 条件下烧结的掺有 2 wt% LiZO 添加剂的示例性掺铌 LLZO 粒子在 25 °C 时的锂+电导率为 8.39 × 10-4 S cm-1,相对密度为 96.8%,并且具有超高的一致性。相信我们的方法为制备固态电池用高性能 LLZO 陶瓷提供了启示。
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In-situ Li2O-atmosphere assisted solvent-free route to produce highly conductive Li7La3Zr2O12 solid electrolyte
Solid-state batteries have garnered attention due to their potentiality for increasing energy density and enhanced safety. One of the most promising solid electrolytes is garnet-type Li7La3Zr2O12 (LLZO) ceramic electrolyte because of its high conductivity and ease of manufacture in ambient air. The complex gas-liquid-solid sintering mechanism makes it difficult to prepare LLZO with excellent performance and high consistency. In this study, an in-situ Li2O-atmosphere assisted solvent-free route is developed for producing the LLZO ceramics. First, the lithium-rich additive Li6Zr2O7 (LiZO) is applied to in-situ supply Li2O atmosphere at grain boundaries, where its decomposition products (Li2ZrO3) build the bridge between the grain boundaries. Second, comparisons were studied between the effects of dry and wet routes on the crystallinity, surface contamination, and particle size of calcined powders and sintered ceramics. Third, by analyzing the grain boundary composition and the evolution of ceramic microstructure, the impacts of dry and wet routes and lithium-rich additive LiZO on the ceramic sintering process were studied in detail to elucidate the sintering behavior and mechanism. Lastly, exemplary Nb-doped LLZO pellets with 2 wt% LiZO additives sintered at 1,300 °C × 1 min deliver Li+ conductivities of 8.39 × 10-4 S cm-1 at 25 °C, relative densities of 96.8%, and ultra-high consistency. It is believed that our route sheds light on preparing high-performance LLZO ceramics for solid-state batteries.
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