Conceptualizing Surface‐Like Diffusion for Ultrafast Ionic Conduction in Solid‐State Materials

Abstract Surface‐like diffusion is a recently proposed concept to explain the mechanism of ultrafast ionic conduction in high‐rate oxide (e. g., niobium oxides and their alloys with TiO 2 and WO 3 ) and framework materials (e. g., Prussian blue analogs). This perspective seeks to illustrate the structural origin, theoretical foundation, and experimental evidences of surface‐like diffusion. Unlike classical lattice diffusion, which typically involves ionic hopping between adjacent interstitial sites in solids, surface‐like diffusion occurs when ions–that are significantly smaller than the interstitials–migrate along the off‐center path in the diffusion channel. This mechanism results in an exceptionally low activation energy ( E a ) down to 0.2 eV, which is crucial for achieving high‐rate performance in electrochemical devices such as lithium‐ion and sodium‐ion batteries. This concept review also discusses the criteria to identify materials with potential surface‐like diffusion and outlines theoretical and experimental tools to capture such phenomenon. Several candidates for further investigation are proposed based on the current understanding of the mechanism.