Electron Localization Enhances Cation Diffusion in Transition Metal Oxides: An Electronic Trebuchet Effect

TL;DR

This paper reveals that electron localization in transition-metal oxides significantly boosts cation diffusion by lowering energy barriers, explaining enhanced ionic mobility under various conditions through a novel electronic effect.

Contribution

It introduces the electronic trebuchet effect, linking electron localization to increased ion mobility and resolving long-standing questions about diffusion in reduced ceramics.

Findings

Electron localization lowers saddle-point energy for ion migration.

Enhanced diffusion observed in reduced zirconia and ceria.

First-principles calculations support the electronic trebuchet mechanism.

Abstract

Ion diffusion is a central part of materials physics of fabrication, deformation, phase transformation, structure stability and electrochemical devices. Conventional theory focuses on the defects that mediate diffusion and explains how their populations influenced by oxidation, reduction, irradiation and doping can enhance diffusion. However, we have found the same influences can also elevate their mobility by orders of magnitude in several prototypical transition-metal oxides. First-principles calculation fundamentally connects the latter observation to migrating ion's local structure, which is inherently soft and has a broken symmetry, making it susceptible to electron or hole localization, thereby realizing a lower saddle-point energy. This finding resolves an unanswered question in physical ceramics of the past 30 years: why cation diffusion against the prediction of classical nonstoichiometric defect physics is enhanced in reduced zirconia, ceria and structurally related ceramics? It also suggests the saddle-point electron-phonon interaction that enables a negative-U state is akin to the counterweight effect that enables a trebuchet. This simple picture for the transitional state explains why enhanced kinetics mediated by radical-like-ion migration occurs often, especially under extreme conditions.