An investigation of ceria's oxygen storage capacity by computer simulation

1. An investigation of ceria's oxygen storage capacity by computer simulation Beth Savoy May 2007

2. Outline • Introduction • Applications of ceria • Ceria lattice • Simulation technique • Results • Conclusions

3. Introduction • Oxygen storage capacity • High oxygen ion conductivity (500-800 °C) • What is studied? • Reduction energy • Defect cluster formation • Full range of mixed oxide Ce(1-x)ZrxO2

4. Applications • Automotive catalyst • Store oxygen in lean conditions / release in rich conditions to remove pollutants • Electrolyte in solid oxide fuel cells (doped) • Oxygen ions move through ceria • Oxygen sensor • Self-cleaning oven

5. Ce Ce Ce O O Ce Ce O O Ce Ce Lattice • 4f15d16s2 • Fluorite structure • CeOx 1.71<x<2

6. LatticeHoles

7. SimulationGULP energy minimization • Born-model – spherical, ionically charged • Energy contributions (Ewald)

8. SimulationPotential parameters

9. mass charge spring spring constant potential C6 term SimulationMean-field approximation • Ce(1-x)ZrxO2

10. ResultsLattice constant

11. SimulationMott-Littleton point defect model ∞ Continuum (fixed lattice positions) r1 Explicit relaxation

12. SimulationVacancy formation Release of oxygen gas Ce4+ at cation lattice point Ce3+ at cation lattice point O2- at anion lattice point Oxygen vacancy

13. SimulationDecomposition of rxn

14. Balducci et. al (2000) Ewald c6 ResultsReduction energies

15. Conclusions • Mean-field approximation good for Ce(1-x)ZrxO2 mixed oxide • Addition of ZrO2 above 50% lowers reduction energy • Association of defect clusters further lowers reduction energy • Ewald summation of short-range attractive terms important for convergence

16. Future work • Surface reduction energies • Already reduced structures • Oxygen migration activation energy Balducci et. al.