The effect of aliovalent dopants on the structural and transport properties of Li6La2BaTa2O12 garnet Li-ion solid electrolytes†

IF 5.2 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY
Marco Amores, Peter J. Baker, Edmund J. Cussen and Serena A. Cussen
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Abstract

Li-rich garnet solid electrolytes are promising candidates for all-solid-state batteries, allowing for increased energy densities, compatibility with Li-metal anodes and improved safety by replacing flammable organic-based liquid electrolytes. Li-stuffed garnets typically require aliovalent doping to stabilise the highly ionic conductive Iad cubic phase. The role of dopants and their location within the garnet framework can greatly affect the conduction properties of these garnets, yet their impact on the structure and resulting ion transport is not fully understood. Here, we evaluate the effect of aliovalent doping with Al3+, Ga3+ and Zn2+ in the Li6BaLa2Ta2O12 (LBLTO) garnet material. A combination of PXRD and XAS reveals a linear cell parameter contraction with an increase in doping and the preference of the 24d Li+ sites for Al3+ and Zn2+ dopants, with Ga3+ occupying both the 24d and 48g Li+ sites. Macroscopic ionic conductivity analyses by EIS demonstrate an enhancement of the transport properties where addition of small amounts of Al3+ decreases the activation energy to Li+ diffusion to 0.35(4) eV. A detrimental effect on ionic conductivities is observed when dopants were introduced in Li+ pathways and upon decreasing the Li+ concentration. Insights into this behaviour are gleaned from microscopic diffusion studies by muon spin relaxation (μ+SR) spectroscopy, which reveals a low activation energy barrier for Li+ diffusion of 0.16(1) eV and a diffusion coefficient comparable to those of Li7La3Zr2O12 (LLZO) benchmark garnet materials.

Abstract Image

别价掺杂剂对 Li6La2BaTa2O12 石榴石锂离子固体电解质结构和传输特性的影响†。
富锂石榴石固体电解质是全固态电池的理想候选材料,可提高能量密度,与锂金属阳极兼容,并通过取代易燃的有机液态电解质提高安全性。锂填充石榴石通常需要异价掺杂,以稳定高离子导电性的 Iad 立方相。掺杂剂的作用及其在石榴石框架中的位置会极大地影响这些石榴石的传导性能,但它们对结构和由此产生的离子传输的影响尚未完全明了。在这里,我们评估了在 Li6BaLa2Ta2O12(LBLTO)石榴石材料中掺入 Al3+、Ga3+ 和 Zn2+ 等价物的效果。结合 PXRD 和 XAS 可以发现,随着掺杂量的增加,电池参数呈线性收缩,Al3+ 和 Zn2+掺杂剂偏好 24d Li+ 位点,而 Ga3+ 则同时占据 24d 和 48g Li+ 位点。通过 EIS 进行的宏观离子传导性分析表明,加入少量 Al3+ 后,Li+扩散的活化能降低到 0.35(4) eV,从而增强了传输特性。在 Li+ 通路中引入掺杂剂以及降低 Li+ 浓度时,离子传导性会受到不利影响。通过μ子自旋弛豫(μ+SR)光谱进行的微观扩散研究揭示了这一行为,该研究显示 Li+ 扩散的低活化能势垒为 0.16(1) eV,扩散系数与 Li7La3Zr2O12 (LLZO) 基准石榴石材料相当。
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 Advances
Materials Advances MATERIALS SCIENCE, MULTIDISCIPLINARY-
CiteScore
7.60
自引率
2.00%
发文量
665
审稿时长
5 weeks
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