6533b7d8fe1ef96bd126991a
RESEARCH PRODUCT
The electronic properties of an oxygen vacancy at ZrO2-terminated (001) surfaces of a cubic PbZrO3: computer simulations from the first principles
Roberts I. EglitisRoberts I. EglitisEugene A. KotominEugene A. KotominAleksejs GopejenkoYu. F. ZhukovskiiDonald E EllisSergei PiskunovSergei Piskunovsubject
Electron densityChemistryBand gapVacancy defectRelaxation (NMR)Supercell (crystal)General Physics and AstronomyPhysical chemistryDensity functional theoryElectronic structurePhysical and Theoretical ChemistryMolecular physicsElectronic densitydescription
Combining B3PW hybrid exchange-correlation functional within the density functional theory (DFT) and a supercell model, we calculated from the first principles the electronic structure of both ideal PbZrO(3) (001) surface (with ZrO(2)- and PbO-terminations) and a neutral oxygen vacancy also called the F center. The atomic relaxation and electronic density redistributions are discussed. Thermodynamic analysis of pure surfaces indicates that ZrO(2) termination is energetically more favorable than PbO-termination. The O vacancy on the ZrO(2)-surface attracts approximately 0.3 e (0.7 e in the bulk PbZrO(3)), while the remaining electron density from the missing O(2-) ion is localized mostly on atoms nearest to a vacancy. The calculated defect formation energy is smaller than in the bulk which should lead to the vacancy segregation to the surface. Unlike Ti-based perovskites, the vacancy-induced (deep) energy level lies in PbZrO(3) in the middle of the band gap.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2008-07-18 | Physical Chemistry Chemical Physics |