Soft-chemical topotactic pathway to (001)-faceted hollandite K-Fe-Ti oxides with accelerated Li⁺ migration

Tunnel-structured hollandite-type oxides hold promise for lithium-ion storage owing to their structural stability and zero-strain characteristics, yet their electrochemical performance is severely constrained by facet-dependent ion transport. Conventional hydrothermal and solid-state routes predominantly expose the (010) facet, where closed lattice channels impose high Li⁺ migration barriers and sluggish kinetics. Here, we develop a soft-chemical topotactic transformation strategy that exploits an iron-containing layered titanate precursor to achieve crystallographically inherited hollandite architectures with preferentially exposed (001) facets. This approach contrasts sharply with strong-acid treatments that yield rod-like (010)-faceted products, thereby providing a direct structural and electrochemical comparison. First-principles calculations reveal that the (001) facet reduces the Li⁺ migration barrier from 0.22 to 0.06 eV, while electrochemical measurements reveal that KFTO with exposed (001) facet exhibits a higher coefficient of 2.23 × 10⁻¹⁵ cm² S⁻¹ than that of KFTO with exposed (001) facet (1.11 × 10⁻¹⁶ cm² S⁻¹). By bridging facet engineering with a controllable synthesis pathway, this work establishes a paradigm for tailoring ion transport in tunnel-structured oxides, offering a generalizable route toward high-performance electrodes for fast-charging and durable energy storage.