化学
快离子导体
离子
离子键合
重整化
扩散
化学物理
凝聚态物理
统计物理学
去相关
离子电导率
散射
重整化群
电解质
导线
不变(物理)
相关函数(量子场论)
电荷(物理)
分子动力学
指数衰减
空间相关性
电导率
物理
缩放比例
离子运输机
作者
Saumya Ranjan Mahanta,Swastika Banerjee
摘要
Ion transport in solids is a key determinant of next-generation energy technologies, especially solid-state batteries, fuel cells, and other electrochemical systems. However, designing a superionic conductor remains challenging because ionic conductivity arises from a coupled interplay among migration barriers, hopping frequencies, and the characteristic diffusion length scales of the mobile sublattice, with no universal mechanism across materials. Although compositional engineering improves diffusion, it is unclear how spatial and temporal correlations govern ion transport. Here, we introduce a relaxation-matched framework that combines intermediate scattering functions with decorrelation-time-resolved van Hove analysis to probe lithium-ion dynamics in pristine (Li 7 La 3 Zr 2 O 12 ), Ga-substituted (Li 6.25 Ga 0.25 La 3 Zr 2 O 12 ), and high-entropy garnets (Li 5.75 Ga 0.25 La 2.5 Nd 0.5 Zr 0.75 Ti 0.25 Hf 0.25 Ce 0.25 Nb 0.25 Ta 0.25 O 12 ). Despite increasing compositional complexity and dynamical heterogeneity, the spatial signatures of Li-ion motion remain invariant at their characteristic decorrelation times, with both local Li-jump and long-range collective displacements collapsing onto a common length scale. However, compositional engineering leads to accelerated decay of ion correlations that compresses the associated time scales while preserving transport geometry. High-entropy substitution amplifies this effect by destabilizing intermediate-range order and promoting a dynamically percolating Li network. This framework provides a general route to disentangle spatial and temporal contributions to transport, identifying time-scale renormalization of correlation decay as a unifying design principle for superionic conductors.
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