M. Ruitenbeek et al., The structure of vanadium oxide species on gamma-alumina; an in situ X-rayabsorption study during catalytic oxidation, TOP CATAL, 10(3-4), 2000, pp. 241-254
The mechanism of catalytic oxidation reactions was studied using in situ X-
ray absorption spectroscopy (XAFS) over a 17.5 wt% V2O5/Al2O3 catalyst, i.e
., at reaction temperatures and in the presence of reactants. It was found
that X-ray absorption near-edge structure (XANES) is a powerful tool to stu
dy changes in the local environment and the oxidation state of the vanadium
centres during catalytic oxidation. At 623 K, the catalyst follows the ass
ociative mechanism in CO oxidation. XAFS revealed that the Mars-van Krevele
n mechanism is operative at 723 K for CO oxidation. The extended X-ray abso
rption fine structure (EXAFS) results showed that the structure of the supp
orted V2O5 phase consists of monomeric tetrahedral (Al-O)(3)-V=O units afte
r dehydration in air at 623 K. However, the residuals of the EXAFS analysis
indicate that an extra contribution has to be accounted for. This contribu
tion probably consists of polymeric vanadate species. The structure remains
unchanged during steady-state CO oxidation at 623 and 723 K. Furthermore,
when oxygen was removed from the feed at 623 K, no changes in the spectra o
ccurred. However, when oxygen is removed from the feed at 723 K, reduction
of the vanadium species was observed, i.e., the vanadyl oxygen atom is remo
ved. The V3+ ion subsequently migrates into the gamma-Al2O3 lattice, where
it is positioned at an Al3+ octahedral position. This migration process app
ears to be reversible; so the (Al-O)(3)-V=O units are thus restored by re-o
xidation.