The interaction of the noble metals Pd and Pt with the {111} and {011} surfaces of cubic-ZrO2 was examined by employing pseudo-potential plane-wave calculations within two Hamiltonians: the LDA and Perdew–Wang91 (GGA). The most favourable adsorption sites, adsorption energies, density of states and electron-charge density distributions are discussed, where the latter properties provide information on the bonding character between the ad-layer and the support, which is directly related to the catalytic activity. Owing to surface relaxation on the Pd/ZrO2{111} interface, we found a competition between the 1-fold and 3-fold oxygen sites; i.e. the differences in adsorption energies between the various adsorption sites are ca. 20 kJ mol−1, which in addition suggests that the Pd-adlayer may have significant mobility.
We anticipated the Pt-adlayer to be associated with lower surface mobility than the Pd-layer, due to the tendency to favour one particular adsorption site: ΔEads on top of Os is ∽100 kJ mol−1, while on top of the 3-fold oxygen sites the energy is ∽60 kJ mol−1. Also, on the {011} surface, Pt is favoured by 1-fold oxygen coordination, while Pd exhibits higher oxygen coordination, and is adsorbed on the terraces of the {011} surface. Our calculations show the metal–support interactions to be mainly of an electrostatic nature, introduced by a polarisation of the metal ad-layers.
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