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Abstract
Expanding the voltage window is a common approach for increasing the practical capacity of the LiCoO2 cathode. However, it brings serious concerns such as structural degradations and the associated oxygen release induced by the transition metal (TM) cation migrations at a highly delithiated state. Therefore, it is crucial to understand the dynamic correlations between the TM cation migrations and the oxygen dimer formation. In this work, machine-learning-potential-assisted molecular dynamics simulations combined with enhanced sampling techniques are performed to resolve the above question using a representative CoO2 model. Our results show that the occurrence of the Co migrations exhibits local characteristics. The formation of two adjacent Co vacancies (the Co vacancy cluster) is necessary for the oxygen dimer generation. We further show that the introduction of the Ti dopant can significantly increase the kinetic barrier of the Co ion migration and thus effectively suppress the formation of the Co vacancy cluster. Overall, our work reveals the atomic-scale dynamic correlations between the TM migrations and the instability of the oxygen sublattice in the cathode material, and provides insights about the mechanism of the dopants promotion on the stability of cathode materials.
Supplementary materials
Title
Unraveling the Dynamic Correlations between Transition Metal Migrations and the Oxygen Dimer Formation in the Layered LiCoO2 Cathode
Description
Details of methodologies; workflow of the tests for determining the most stable spin configurations and the distribution of magnetic-moment projections for the Li/Co/O ions in the O3 phase Li6Co12O24; workflow of the dataset generation for the bulk LixCoO2; barriers of the Co cross-layer migration with a perfect oxygen sublattice, and the intralayer and interlayer oxygen dimer combination with all the TM ions located in the stable octahedral sites in the TM layer; barriers of the interlayer Co migration order and the intralayer Co migration order in the presence of one Co vacancy in the TM layer accompanied with a Co ion in the Li layer; barriers of the interlayer oxygen dimer formation in the presence of a single Co vacancy and a Co vacancy cluster in the CoO2 model; convergence tests for the KSPACING and cutoff energy.
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