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Among the chloride-based Li-ion solid electrolytes, Li₂ZrCl₆ (LZC) have emerged as potential candidates due to their affordability, moisture stability, and high ionic conductivity. LZC synthesized by solid-state heating exhibits limited Li-ion conductivity while the mechanochemical ball-milled material is more conductive. In this computational study, we integrate thermodynamic modeling, using cluster-expansion Monte Carlo, and kinetic modeling, using molecular dynamics, to investigate whether cation disorder can be achieved in LZC, and how it affects Li-ion transport. Our results indicate that fast Li-ion conductivity is induced by the activation of Li/vacancy disorder, which itself depends on the degree of Zr disorder. We find that the very high-temperature scale at which equilibrium Zr-disorder can form precludes any equilibrium synthesis processes for achieving fast Li-ion conductivity, rationalizing why only non-equilibrium synthesis methods, such as ball milling leads to good conductivity. We identify as the critical mechanism the lack of Li/vacancy disorder near room temperature when Zr is well-ordered. Our simulations further show that the Li/vacancy order-disorder transition temperature is lowered by Zr disorder, which is necessary for creating high Li diffusivity at room temperature. The insights obtained from this study raise a challenge for the large-scale production of these materials and the potential for the long-term stability of their properties.
Zhong et al. (Wed,) studied this question.