Layered LiCoO has drawn tremendous attention as a modeling cathode for Li-ion batteries, while its structural instability, especially in the high delithiation region, remains unsolved. With the aim of revealing the structural fundamentals, LiCoO electrodes are investigated at a long delithiation range using both in situ and ex situ techniques. In the highly delithiated LiCoO electrode, the unique charge compensation process leads to a spatial charge gradient of Co/Co/Co ions from surface to bulk, which can be further manipulated by structural distortion, Li extraction, and surface side reactions. The coordinated surface oxygen is shown to be electrochemically active and fully reversible in participating in the charge compensation during cycling. Moreover, the active lattice O can be significantly stabilized by introducing the undesired surface Li-Co antisites, which also play an effective role in accommodating the internal stress induced by volume changes. These findings effectively bridge the structural changes with the Li/e migration kinetics to elucidate the degradation of LiCoO cathode upon delithiation, demonstrating a rewarding avenue for improving the electrochemical performance of LiCoO itself and developing high energy density cathodes for the battery community as well.
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