Theoretical analysis of the adsorption of phosphoric acid and model phosphate monoesters on CeO2(111)

Document Type

Article

Publication Date

3-1-2021

Abstract

Ceria has been shown to catalyze the dephosphorylation of phosphate monoesters at ambient temperature. As a step toward understanding the reaction mechanism on ceria, first-principles density functional theory calculations in the GGA-PW91+U approach have been carried out to study the adsorption of phosphoric acid and two model phosphate monoesters, methyl phosphate and para-nitrophenyl phosphate, on CeO2(111). Consistent patterns are found in terms of energetic, structural, electronic, and vibrational properties upon adsorption. For the parent molecules, bonding of the phosphorous atom directly to a surface lattice oxygen atom (Olatt) is the only stable molecular adsorption state. Common entities that reduce Ce4+ to Ce3+ (e.g., co-adsorbed H atom, surface and subsurface oxygen vacancy) mildly perturb the P-Olatt bond, but Ce3+ by itself has only a negligible effect. Deprotonation is exothermic for all three phosphate species on CeO2(111), much more so if they are adsorbed in an oxygen vacancy via a phosphoryl O than on a stoichiometric surface. Infrared spectra have been simulated for the adsorbed states of the model phosphates for comparison with future experiments.

Publication Source (Journal or Book title)

Surface Science

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