The influence of the carrier (i.e., SiO2, ZrO2, TiO2, gamma-Al2O3, and MgO)
on the reduction pattern, the acid-base properties, and the catalytic acti
vity of supported tin dioxide catalysts has been investigated by temperatur
e-programmed reduction/oxidation, adsorption calorimetry, and reduction of
NOx by ethene in an oxygen-rich atmosphere. Two series of SnO2 catalysts of
low (similar to 3 wt%) and high (similar to 20 wt%) Sn content were prepar
ed by impregnation. The dramatic influence of the support on the activity a
nd selectivity of the SnO2 surfaces in the NO reduction by C2H4 was evidenc
ed. For the 3 wt% Sn series, 39, 38, 29, 24, and 0% conversions of 5000 ppm
NO to N-2 in the presence of 90,000 ppm of O-2 at a space velocity of 50,0
00 h(-1) were observed at 500 degrees C on ZrO2, Al2O3, TiO2, SiO2, and MgO
supports, respectively. The most active catalysts at low Sn loading were t
hose based on ZrO2 and Al2O3 The integral N-2 formation rates per mole of S
nO2 ranged from 2 to 5 x 10(-3) s(-1) in the 350-500 degrees C temperature
domain. An increase of the Sn loading led to small positive or negative eff
ects on the extent of the NO reduction depending on the support. A direct r
elationship between reducibility and catalytic activity has also been obser
ved. Above monolayer coverage, the molecular structures of SnO2 play an imp
ortant role. For the 20 Sn wt% series, the reducibility scale for Sn-IV-->S
n-II, based on the temperature at the maximum of the reduction peak, is in
the order SnSi-20 > SnTi-20 > SnAl-20 > SnZr-20, while the competitiveness
factor increases in the same order. Finally, it appears that a relatively s
trong acidity is necessary for good catalytic performance, but no direct co
rrelation between the number of acid sites and the catalytic activity was o
bserved. (C) 2000 Academic Press.