Sodium-ion solid electrolytes offer a sustainable route toward next-generation batteries, but few match the performance of lithium counterparts. Halide-based NaMOCl4 (M = Nb, Ta) has recently emerged as a promising analogue to LiMOCl4, yet its structure-transport relationships remain unclear due to poor crystallinity in experiments. Here, we combine density functional theory and machine-learned molecular dynamics to reveal that crystalline NaMOCl4 exhibits negligible room-temperature conductivity, with high activation barriers arising from vacancy-mediated diffusion below an order-disorder transition. Above this transition, rotational and translational motion of the MO2/2Cl4 chains creates new Na sites and enhances transport. In contrast, the amorphous phase inherently supports facile, three-dimensional Na diffusion through dynamic framework flexibility. These results show that ordered crystalline phases hinder ionic transport, while disorder – either thermally induced or structural – facilitates it, revising prior assumptions from the Li system and providing design principles for high-conductivity Na halide electrolytes.
Lauren N. Walters, Yuxing Fei, Bernardus Rendy, Xiaochen Yang, Mouhamad Diallo, KyuJung Jun, Grace Wei, Matthew J. McDermott, Andrea Giunto, Tara P. Mishra, Fengyu Shen, David Milsted, May Sabai Oo, Haegyeom Kim, Michael C. Tucker, Gerbrand Ceder
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