电导率
中子衍射
材料科学
放电等离子烧结
离子电导率
价(化学)
离子
电化学窗口
对分布函数
分析化学(期刊)
快离子导体
烧结
晶体结构
化学
结晶学
物理化学
电解质
电极
复合材料
色谱法
数学
数学分析
有机化学
作者
Ruoyu Dai,Maxim Avdeev,Seung‐Joo Kim,R. Prasada Rao,Stefan Adams
标识
DOI:10.1021/acs.chemmater.2c02640
摘要
LiTa2PO8 has recently been reported as a new fast Li-ion conducting structure type within the series of Lix(MO6/2)m(TO4/2)n polyanion oxides. Here, we demonstrate the preparation of LiTa2PO8 by solid-state syntheses, clarify the temperature dependence of lithium distribution and ionic conductivity, and study the structural stability, densification, and achievable total conductivity as a function of sintering conditions synergizing experimental neutron and X-ray powder diffraction and electrochemical studies with computational energy landscape analyses and molecular dynamics simulations. A total room temperature conductivity of 0.7 mS cm–1 with an activation energy of 0.27 eV is achieved after sintering at 1323 K for 10 h. Spark plasma sintering yields high densification >98%, highly reproducible bulk conductivities of 2.8 mS cm–1, in agreement with our bond valence site energy-based pathway predictions, and total conductivities of 0.6 mS cm–1 within minutes. Powder diffraction studies from 3 to 1273 K reveal a reversible flipping of the monoclinic angle from above to below 90° close to room temperature as a consequence of rearrangements of the mobile ions that change the detailed pathway topology. A consistent model of the temperature-dependent Li redistribution, conductivity anisotropy, and transport mechanism is derived from a synopsis of diffraction experiments, experimental conductivity studies, and simulations. Due to the limited electrochemical window of Lix(TaO6/2)2(PO4/2)1 (LTPO), a direct contact with Li metal or high voltage cathode materials leads to degradation, but as demonstrated in this work, semi-solid-state batteries, where LTPO is protected from direct contact with lithium by organic buffer layers, achieve stable cycling.
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