(600ai) Phase Transition of Ceria Using First Principles Calculations | AIChE

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(600ai) Phase Transition of Ceria Using First Principles Calculations

Authors 

Mhadeshwar, A. B., University of Connecticut
Ramprasad, R., University of Connecticut


            Ceria can undergo phase
transformation from its stable stoichiometric ratio at ambient conditions to a
lower oxygen content material with increasing temperature and decreasing oxygen
partial pressure, while preserving its fluorite structure (Fm-3m). However at a
critical O/Ce ratio of 1.5, the hexagonal structure (P3/m1) of ceria becomes
more prevalent.1,2 The transition from a stoichiometric to
non-stoichiometric ceria creates oxygen vacancies along with cerium atoms with
a reduced oxidation state.3,4 Such characteristics make ceria a promising
material for catalytic reactions.1,5 One such case is the application
of ceria in the Water-Gas Shift (WGS) reaction, where metals supported on ceria
exhibit higher activities compared to no ceria support or a different support
material.6,7,8 Our work probes an atomic level understanding of the
nature of ceria over a wide range of temperature and pressure conditions using
Density Functional Theory (DFT) and First Principle Thermodynamics (FPT). The most
stable ceria (111) surface9,10 is modeled using a periodic 2x2 supercell image, as shown in Figure
1. More than 25 configurations of oxygen concentrations are considered to
determine the stable phases in a wide temperature pressure region. This is the
first ever comprehensive first principles investigation to predict the phase
transition of ceria under various operating conditions.

\Users\Venkatesh\Documents\University of Connecticut\Research\Next Generation Catalyst Design\Presentations\Pictures for Presentations\CeO2_5L_1molO_2x2.jpg\Users\Venkatesh\Documents\University of Connecticut\Research\Next Generation Catalyst Design\Presentations\Pictures for Presentations\CeO2_5L_1molO_2x2 slab.jpg  

Left: Top view
and Right: Side view of the ceria (111) plane. Blue: adsorbed oxygen; red:
surface oxygen; black: sub-surface oxygen; green: surface cerium; and grey: cerium
in the second layer.

References

1.    
Trovarelli, A. ?Catalytic properties of ceria and CeO2-containing
materials? Catalysis Reviews 38 (1996): 439-520.

2.    
Zinkevich, M et al. ?Thermodynamic modelling of the cerium?oxygen
system.? Solid State Ionics 177 (2006): 989-1001.

3.    
Nolan, M. et al. ?Oxygen vacancy formation and migration in
ceria? Solid State Ionics 177 (2006): 3069-3074.

4.    
Torbrügge, S. et al. ?Evidence of subsurface oxygen vacancy
ordering on reduced CeO2(111)? Physical Review Letters 99
(2007): 1-4.

5.     Rao, G and Mishra,
B. ?Structural, redox and catalytic chemistry of ceria based materials.? Bulletin
of the Catalysis Society of India 2 (2003): 122-134.

6.     Wheeler, C. et
al. ?The water?gas-shift reaction at short contact times.? Journal of
Catalysis 223 (2004): 191-199.

7.    
Hilaire, S. et al. ?A comparative study of water-gas-shift
reaction over ceria supported metallic catalysts? Applied Catalysis 215
(2001): 271-278.

8.    
Gorte, R. and Zhao S. ?Studies of the water-gas-shift reaction with
ceria-supported precious metals? Catalysis Today 104 (2005): 18-24.

9.    
Nolan, M. et al. ?The electronic structure of oxygen vacancy
defects at the low index surfaces of ceria? Surface Science 595 (2005):
223-232.

10.  Désaunay, T. et
al. ?Modeling basic components of solid oxide fuel cells using density
functional theory: Bulk and surface properties of CeO2.? Surface
Science 606 (2012): 305-311.

See more of this Session: Poster Session of Catalysis and Reaction Engineering (CRE) Division

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Topics 

Catalysis
Thermodynamics

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