Abstract
The dependence of the lattice parameter on dopant concentration in Ce1-xMxO2 (M = Sn and Ti) solid solutions is not linear. A change towards a steeper slope is observed around x ∼ 0.35, though the fluorite structure (space group Fm3m) is preserved up to x = 0.5. This phenomenon has not been observed for Ce1-xZrxO2 solid solutions showing a perfectly linear decrease of the lattice parameter up to x = 0.5. In order to understand this behavior, the oxidation state of the metal ions, the disorder in the oxygen substructure and the nature of metal-oxygen bonds have been analyzed by XPS, (119)Sn Mössbauer spectroscopy and X-ray absorption spectroscopy. It is observed that the first Sn-O coordination shell in Ce1-xSnxO2 is more compact and less flexible than that of Ce-O. The Sn coordination remains symmetric with eight equivalent, shorter Sn-O bonds, while Ce-O coordination gradually splits into a range of eight non-equivalent bonds compensating for the difference in the ionic radii of Ce(4+) and Sn(4+). Thus, a long-range effect of Sn doping is hardly extended throughout the lattice in Ce1-xSnxO2. In contrast, for Ce1-xZrxO2 solid solutions, both Ce and Zr have similar local coordination creating similar rearrangement of the oxygen substructure and showing a linear lattice parameter decrease up to 50% Zr substitution. We suggest that the localized effect of Sn substitution due to its higher electronegativity may be responsible for the deviation from Vegard's law in Ce1-xSnxO2 solid solutions.
Highlights
IntroductionDue to their excellent oxygen storage/release properties, CeO2 based oxides have been used as excellent supports for noble as well as transition metals promoting various catalytic reactions
The oxygen storage capacity (OSC) of CeO2 plays a unique role in mediating crucial oxygen exchange processes during catalytic reactions in auto-exhaust catalysis.[1,20]
CeO2 matrix enhance the reducibility, thermal stability, oxygen storage capacity and catalytic activities of CeO2.4 The abovementioned solid solutions have been used as supports for noble metals like Pt, Pd, Rh, and Ru leading to a better catalytic activity for a variety of reactions at comparatively low temperatures.[4]
Summary
Due to their excellent oxygen storage/release properties, CeO2 based oxides have been used as excellent supports for noble as well as transition metals promoting various catalytic reactions. The oxygen storage capacity (OSC) of CeO2 plays a unique role in mediating crucial oxygen exchange processes during catalytic reactions in auto-exhaust catalysis.[1,20] In the efforts to enhance the OSC of CeO2 by various cation substitution reactions, the tetravalent cations such as Ti4+, Sn4+, and Zr4+ have been found to be effective in creating more labile oxygen through structural changes in the Ce1ÀxMxO2 solid solutions.[4,21,22] Such substitutions of isovalent as well as aliovalent transition metals into the. CeO2 matrix enhance the reducibility, thermal stability, oxygen storage capacity and catalytic activities of CeO2.4 The abovementioned solid solutions have been used as supports for noble metals like Pt, Pd, Rh, and Ru leading to a better catalytic activity for a variety of reactions at comparatively low temperatures.[4].
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