Anti-phase boundaries (APBs) are observed in as synthesized and processed LiCoO2, which is used widely as a cathode material. Using a combination of scanning transmission electron microscopy and ab initio simulations, we investigate APB formation, structure, stability, and impact on Li ion diffusion. It is found that APB low-coordinated sites give rise to cation defects which, in turn, provide a variety of APB structures. Li diffusion along an APB can enter a correlated mode, leading to a ~40% decrease in activation energy with respect to that for the uncorrelated hopping of Li ions. We propose that APBs function as additional mass transfer channels that couple in-plane Li ion diffusion pathways, thus, facilitating Li transfer from one two-dimensional basin to another, potentially enabling new energy storage architectures.
Revised: October 9, 2020 |
Published: September 4, 2018
Citation
Ong P., Z. Yang, P.V. Sushko, and Y. Du. 2018.Formation, Structural Variety, and Impact of Anti-Phase Boundaries on Li Diffusion in LiCoO2 Thin Film Cathodes.The Journal of Physical Chemistry Letters 9, no. 18:5515-5520.PNNL-SA-137774.doi:10.1021/acs.jpclett.8b02185