2D–3D structural transition in sub-nanometer PtN clusters supported on CeO2(111)

Abstract

Transition metal particles dispersed on oxide supports are used as heterogeneous catalysts in numerous applications. One example is platinum clusters supported on ceria which is used in automotive catalysis. Although control at the nm-scale is desirable to open new technological possibilities, there is limited knowledge both experimentally and theoretically regarding the geometrical structure and stability of sub-nanometer platinum clusters supported on ceria. Here we report a systematic, Density Functional Theory (DFT) study on the growth trends of CeO₂(111) supported Pt_N clusters (N = 1–10). Using a global optimization methodology as a guidance tool to locate putative global minima, our results show a clear preference for 2D planar structures up to size Pt₈. It is followed by a structural transition to 3D configurations at larger sizes. This remarkable trend is explained by the subtle competition between the formation of strong Pt–O bonds and the cluster internal Pt–Pt bonds. Our calculations show that the reducibility of CeO₂(111) provides a mechanism to anchor Pt_N clusters where they become oxidized in a two-way charge transfer mechanism: (a) an oxidation process, where O_surface atoms withdraw charge from Pt atoms forming Pt–O bonds, (b) surface Ce⁴⁺ atoms are reduced, leading to Ce³⁺. The active role of the CeO₂(111) support in modifying the structural and eventually the chemical properties of sub-nanometer Pt_N clusters is computationally demonstrated.