Harnessing the topotactic transition in oxide heterostructures for fast and high-efficiency electrochromic applications

High-speed, high-performance electrochromic devices can be designed using unique solid-solid phase changes induced by oxygen flow. Mobile oxygen vacancies offer a substantial potential to broaden the range of optical functionalities of complex transition metal oxides due to their high mobility and the interplay with correlated electrons. Here, we report a large electro-absorptive optical variation induced by a topotactic transition via oxygen vacancy fluidic motion in calcium ferrite with large-scale uniformity. The coloration efficiency reaches ~80 cm 2 C −1 , which means that a 300-nm-thick layer blocks 99% of transmitted visible light by the electrical switching. By tracking the color propagation, oxygen vacancy mobility can be estimated to be 10 −8 cm 2 s −1 V −1 near 300°C, which is a giant value attained due to the mosaic pseudomonoclinic film stabilized on LaAlO 3 substrate. First-principles calculations reveal that the defect density modulation associated with hole charge injection causes a prominent change in electron correlation, resulting in the light absorption modulation. Our findings will pave the pathway for practical topotactic electrochromic applications.