Morphology-dependent Li+ ion dynamics in X-ray amorphous and crystalline Li3PS4 prepared by solvent-assisted synthesis

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Jonas Spychala, Christoph Mandl, Katharina Hogrefe, Martin Wilkening, Bernhard Gadermaier
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Abstract

Solid-state electrolytes with high ionic conductivity will be crucial for future energy storage systems. Among many possible materials, thiophosphates offer both favourable mechanical properties and fast ionic transport. β-Li3PS4, as a member of the thiophosphate family, has gained recent attention, due to its remarkable increase in Li+ ionic conductivity when prepared via solvent-assisted synthesis. Despite earlier studies, the lithium ion migration processes causing the increased conductivity remain, however, still uncertain. Here, we study both long-range cation transport and local Li+ jump processes by broadband impedance spectroscopy and nuclear magnetic resonance (NMR), respectively. In particular, we focus on the comparison between mechanochemical and solvent-assisted synthesis to determine the origin of the increased ionic conductivity observed in the latter. Our measurements reproduce the previously reported high ionic conductivity and reveal that synthesis conditions significantly affect the Arrhenius pre-exponential factor governing ionic conductivity. Diffusion-controlled 7Li (and 31P) NMR spin relaxation rates confirm rapid, anisotropic lithium ion hopping that is characterized by timescale-dependent activation energies Ea ranging from 0.40 eV (long-range transport, as also seen by conductivity spectrosocpy) to values down to 0.09 eV (local barries).
溶剂辅助合成法制备的 X 射线无定形和晶体 Li3PS4 中与形态有关的 Li+ 离子动力学
具有高离子传导性的固态电解质对未来的能量储存系统至关重要。在众多可能的材料中,硫代磷酸盐既具有良好的机械性能,又能实现快速离子传输。β-Li3PS4 作为硫代磷酸盐家族的一员,在通过溶剂辅助合成法制备时显著提高了锂离子电导率,因此近年来备受关注。尽管早前已有研究,但导致电导率增加的锂离子迁移过程仍不确定。在此,我们通过宽带阻抗光谱和核磁共振(NMR)分别研究了长程阳离子迁移和局部 Li+ 跃迁过程。我们特别关注机械化学合成与溶剂辅助合成之间的比较,以确定后者离子电导率增加的原因。我们的测量结果再现了之前报道的高离子电导率,并揭示出合成条件会显著影响支配离子电导率的阿伦尼乌斯前指数因子。扩散控制的 7Li(和 31P)核磁共振自旋弛豫率证实了快速、各向异性的锂离子跳跃,其特点是随时间刻度变化的活化能 Ea,范围从 0.40 eV(长程传输,电导率光谱也能看到)到低至 0.09 eV 的值(局部条带)。
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
CiteScore
7.20
自引率
4.30%
发文量
567
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