Abstract
We use GGA + U methodology to model the bulk and surface structure of varying stoichiometries of the (001) surface of LiCoO2. The DFT energies obtained for these surface-slab models are used for two thermodynamic analyses to assess the relative stabilities of different surface configurations, including hydroxylation. In the first approach, surface free energies are calculated within a thermodynamic framework, and the second approach is a surface-solvent ion exchange model. We find that, for both models, the -CoO-H1/2 surface is the most stable structure near the O-rich limit, which corresponds to ambient conditions. We find that surfaces terminated with Li are higher in energy, and we go on to show that H and Li behave differently on the (001) LiCoO2 surface. The optimized geometries show that terminal Li and H occupy nonequivalent surface sites. In terms of electronic structure, Li and H terminations exhibit distinct bandgap characters, and there is also a distinctive distribution of charge at the surface. We go on to probe how the variable Li and H terminations affect reactivity, as probed through phosphate adsorption studies. (Graph Presented).
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CITATION STYLE
Huang, X., Bennett, J. W., Hang, M. N., Laudadio, E. D., Hamers, R. J., & Mason, S. E. (2017). Ab Initio Atomistic Thermodynamics Study of the (001) Surface of LiCoO2 in a Water Environment and Implications for Reactivity under Ambient Conditions. Journal of Physical Chemistry C, 121(9), 5069–5080. https://doi.org/10.1021/acs.jpcc.6b12163
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