Microscopic dynamics of lithium diffusion in single crystal of the solid-state electrolyte La2/3-xLi3xTiO3 (x=0.13) studied by quasielastic neutron scattering

Abstract

Quasielastic neutron scattering (QENS) measurements combined with first principles based moleculardynamics calculations were conducted to study the dynamics of Li+ ions in a solid-state electrolyte La2/3-xLi3xTiO3 (LLTO) with x=0.13. By using a large 7Li-enriched single crystal sample, a QENS signal was clearly observed along the three principal axes [110], [111], and [001] at a temperature (T) of 600 K. Wave vector dependence of the linewidth of the QENS signal along each direction was explained well using the Chudley-Elliot model for jumps between the A sites of the perovskite lattice through the bottleneck square, which was also supported by molecular dynamics calculations. At T=600 K, the estimated self-diffusion coefficient of Li+ (DLi) in the ab plane [DabLi=(6.80.5)× 10-6 cm2/s] was slightly larger than that along the c axis [DcLi=(4.40.3)× 10-6 cm2/s], suggesting quasi-isotropic diffusion, that is, the three-dimensional diffusion of Li+ ions. The decrease in DLi with decreasing T was reasonably explained by a thermal activation process with the activation energy determined from ionic-conductivity measurements. Furthermore, the estimated values of the self-diffusion coefficient of Li+ ions are comparable to those in the sulfide-based Li+ ion conductor, Li7P3S11, although its ionic conductivity is 10 times larger than that for LLTO. The obtained microscopic information on Li+ diffusion in LLTO clarifies how to understand the Li conduction mechanism in LLTO and Li7P3S11 in a unified manner and can provide a way to increase the Li+ ionic conductivity in oxide-based solid electrolytes.