K. Shimizu et al., Silver-alumina catalysts for selective reduction of NO by higher hydrocarbons: structure of active sites and reaction mechanism, APP CATAL B, 30(1-2), 2001, pp. 151-162
Citations number
31
Categorie Soggetti
Physical Chemistry/Chemical Physics","Environmental Engineering & Energy
Silver-alumina catalysts prepared by sol-gel method (Ag-Al2O3) and impregna
tion method (Ag/Al2O3) were studied for the selective catalytic reduction (
SCR) of NO by higher alkanes (n-hexane and n-octane). UV-VIS and Ag K-edge
XAFS results established the structure of the catalysts; below 2 wt.%, high
ly dispersed Ag+ ions are predominant Ag species, while at higher Ag loadin
g, Ag-n, clusters are predominant. A relationship between the structure of
Ag species and their catalytic function for SCR by n-octane was clarified.
Ag+ ions are responsible for the selective reduction of NO to N-2, while th
e Ag-n, clusters are responsible for the hydrocarbon combustion and N2O for
mation. The mechanism of SCR by n-hexane on Ag-Al2O3, which mainly consists
of Ag+ ions, were investigated by in situ FTIR spectroscopy. During NO + n
-hexane + O-2 reaction, the acetate produced via the partial oxidation of n
-hexane and the nitrates produced via the oxidation of NO were main adspeci
es in the steady-state condition at 473-623 K. The acetate, which was stabl
e in O-2 or NO, was reactive in NO + O-2. Nitrates, which were relatively s
table in n-hexane, were quite reactive toward n-hexane + O-2. The rate of n
itrates reaction in n-hexane + O-2 was close to the steady-state rate of NO
reduction over wide range of temperature, indicating that the nitrate is a
possible intermediate in the SCR. A proposed mechanism, suggesting the rea
ction of nitrates with partially oxidized hydrocarbon species as a crucial
step, explains the steady-state kinetic results. At relatively high NO conc
entration or at low temperature, nitrates should inhibit the reaction by st
rongly adsorbing on the catalyst surface. (C) 2001 Elsevier Science B.V. Al
l rights reserved.