M. Haneda et al., OXYGEN STORAGE CAPACITY (OSC) AND ACTIVE OXYGEN SPECIES OF ALUMINA-SUPPORTED NONSTOICHIOMETRIC CERIUM OXIDE CATALYSTS, Nippon kagaku kaishi, (3), 1997, pp. 169-179
Structural effect and oxygen storage capacity (OSC) on alumina-support
ed cerium oxide catalysts have been studied. The behavior and activity
of active oxygen species originated from OSC also have been character
ized. In those catalysts, the catalyst prepared by an alkoxide method
using needle boehmite sol derived from aluminum tri-isopropoxide (AIP)
and cerium nitrate dissolved in ethylene glycol gave a finely-divided
nonstoichiometric cerium oxide dispersed on alumina (CeO2-x/Al2O3) af
ter the H-2 reduction at 900 degrees 0. The presence of a finely-divid
ed nonstoichiometric cerium oxide containing Ce3+ and Ce4+ ions was an
ticipated by XRD, EXAFS and fluorescent measurements. The higher OSC w
as achieved on CeO2-x/Al2O3 catalyst, compared with CeO2/Al2O3 and CeA
lO3/Al2O3 where cerium oxides were stoichiometric structures. It was c
oncluded by O-18 tracer studies that the higher activity of CeO2-x/Al2
O3 catalyst for methane oxidation was mainly associated with the activ
ation sites of oxygen species, where the sites consisted of oxygen vac
ancies formed by finely-divided nonstoichiometric structures, from the
surface to the bulk and vice versa. The addition of palladium to CeO2
-x/Al2O3 catalyst enhanced drastically the OSC and improved the cataly
tic activity on NO decomposition by the acceleration of oxygen spillov
er, indicating the generation of synergetic effect between Pd and CeO2
-x. The good relation between OSC and NO decomposition activity on Pd/
CeO2-x/Al2O3 catalyst might promise the preparation of new catalyst by
the control of OSC.