The relative stability of nine different well defined CeO2 surfaces has been studied by periodic density functional calculations using GGA + U and B3LYP exchange-correlation functional. Both methods consistently predict that CeO2(111) is the most stable surface and also provide a consistent picture of the most stable surfaces which indeed are in agreement with previous studies based on empirical interatomic potentials. The facility of ceria surfaces to undergo a redox process has been investigated by forcing spin-polarized solutions, which lead to the occupancy of Ce 4f orbitals. These calculations provide evidence that surfaces with low-coordinated Ce cations are likely to be reduced more easily than regular low-index Miller surfaces.
Relative Stabilities of Low Index and Stepped CeO2 Surfaces from Hybrid and GGA plus U Implementations of Density Functional Theory / M. M., Branda; R. M., Ferullo; Causa', Mauro; F., Illas. - In: JOURNAL OF PHYSICAL CHEMISTRY. C. - ISSN 1932-7447. - 115:(2011), pp. 3716-3721. [10.1021/jp111427j]
Relative Stabilities of Low Index and Stepped CeO2 Surfaces from Hybrid and GGA plus U Implementations of Density Functional Theory
CAUSA', Mauro;
2011
Abstract
The relative stability of nine different well defined CeO2 surfaces has been studied by periodic density functional calculations using GGA + U and B3LYP exchange-correlation functional. Both methods consistently predict that CeO2(111) is the most stable surface and also provide a consistent picture of the most stable surfaces which indeed are in agreement with previous studies based on empirical interatomic potentials. The facility of ceria surfaces to undergo a redox process has been investigated by forcing spin-polarized solutions, which lead to the occupancy of Ce 4f orbitals. These calculations provide evidence that surfaces with low-coordinated Ce cations are likely to be reduced more easily than regular low-index Miller surfaces.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
