Comparison of Lithium Diffusion in Isostructural Ta<sub>12</sub>MoO<sub>33</sub> and Nb<sub>12</sub>MoO<sub>33</sub>: Experimental and Computational Insights from Single Crystals
Md Abdullah Al Muhit, Sean Wechsler, Zachary J. L. Bare, CJ Sturgill, Navindra Keerthisinghe, Matthias A. Grasser, Gregory Morrison, Christopher Sutton, Morgan Stefik, Hans‐Conrad zur Loye
Abstract
The demand for fast charging requires high-performance battery materials with improved ionic transport. Wadsley–Roth (WR) structures have garnered attention, where the combination of blocks and shear planes addresses ionic and electronic conductivity, respectively. An improved understanding of structure–property relationships could lead to higher-performance materials. Herein, we report the first single-crystal structures of Nb 12 MoO 33 and Ta 12 MoO 33 that are consistent with other (3 × 4 × ∞) WR phases. The lithiation of Ta 12 MoO 33 is reported to enable an isostructural comparison with Nb 12 MoO 33 . These two compounds have similar unit cell volumes and atomic radii, where the Ta 12 MoO 33 unit cell is 0.2 vol % smaller. Despite the similarities in structure, the lithiation capacities, voltage windows, C rate-dependent capacities, and ionic diffusivities are distinctly different. These experimental trends align well with density functional theory calculations showing (1) a lower activation energy for Li transport within Ta 12 MoO 33 consistent with its measured 1.5–4.9-fold higher diffusion coefficients (lithiation) and (2) an ∼25% greater measured lithiation stoichiometry for Nb 12 MoO 33, which is attributed to the calculated smaller octahedral distortions (compared to Ta 12 MoO 33 ). These findings reveal that smaller channels in Ta 12 MoO 33 stabilize the transition state with 5-fold coordination, which both decreases the activation energy for diffusion and limits the extent of lithiation. Such structure–property trends help in the search for next-generation battery materials.