6533b86ffe1ef96bd12cd4a5
RESEARCH PRODUCT
Adsorption of atomic and molecular oxygen on the LaMnO3(001) surface: ab initio supercell calculations and thermodynamics.
Yuri A. MastrikovYuri A. MastrikovJoachim MaierEugene A. KotominEugene A. KotominEugene Heifetssubject
AdsorptionChemistryAb initio quantum chemistry methodsVacancy defectAtomBinding energyAb initioGeneral Physics and AstronomyPhysical chemistryMoleculeThermodynamicsPhysical and Theoretical ChemistrySurface energydescription
We present and discuss the results of ab initio DFT plane-wave supercell calculations of the atomic and molecular oxygen adsorption and diffusion on the LaMnO(3) (001) surface which serves as a model material for a cathode of solid oxide fuel cells. The dissociative adsorption of O(2) molecules from the gas phase is energetically favorable on surface Mn ions even on a defect-free surface. The surface migration energy for adsorbed O ions is found to be quite high, 2.0 eV. We predict that the adsorbed O atoms could penetrate the electrode first plane when much more mobile surface oxygen vacancies (migration energy of 0.69 eV) approach the O ions strongly bound to the surface Mn ions. The formation of the O vacancy near the O atom adsorbed atop surface Mn ion leads to an increase of the O-Mn binding energy by 0.74 eV whereas the drop of this adsorbed O atom into a vacancy possesses no energy barrier. Ab initio thermodynamics predicts that at typical SOFC operation temperatures (approximately 1200 K) the MnO(2) (001) surface with adsorbed O atoms is the most stable in a very wide range of oxygen gas pressures (above 10(-2) atm).
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2008-07-31 | Physical chemistry chemical physics : PCCP |