(216c) Steam Effect on NoX Reduction over Pt-Bao/Al2O3 Catalyst
AIChE Annual Meeting
2005
2005 Annual Meeting
Catalysis and Reaction Engineering Division
Fundamentals of Environmental Catalysis II
Tuesday, November 1, 2005 - 1:06pm to 1:24pm
Pt-BaO/Al2O3 is a lean NOx trap (LNT) model catalyst that provides a very effective method for NOx removal in lean-burn gasoline engine exhaust. For a typical cyclic operation, NO is oxidized to NO2 on the Pt sites, and the NO2 is then being trapped by the BaO to form barium nitrate during the lean cycle. During the rich cycle, the nitrate decomposes and the released NOx is reduced on the Pt sites into N2. Many studies have been carried out on catalytic reduction of NO by H2, CO, and by a mixture of H2/CO over supported Pt group metal catalysts. With H2 as reductant, NH3 or HCN is the major reaction product. Steam effects in three-way catalysts have also been widely investigated, and recently the formation of NH3 was reported for the reduction of NO by CO in the presence of water vapor on Al2O3-supported Pt catalyst. Although NH3 is currently not an emission component regulated by EPA, it is still interesting to study in more detail the catalytic formation of NH3 and its influence on the NOx reduction for automotive applications, especially in view of potential use of H2 in future H2 internal combustion engines (ICE).
In this work, we investigated the decomposition characteristics of Pt-Ba(NO3)2/Al2O3 by TGA-IR, and the lean/rich (L/R) cycle reaction characteristics of a Pt-BaO/Al2O3 LNT model catalyst, focusing on the formation of NH3 and exploring ways to minimize the NH3 formation when CO or hydrocarbons are used as reductants. TGA-IR results showed that the original main decomposition products NO2 and NO obtained under N2 atmosphere transfer to NH3 and H2O in presence of H2 atmosphere. The influences of BaO loading, the presence of Pt, and the TGA heating rate on the decomposition temperature and product distribution are discussed. L/R cycle experiments showed that under rich condition the major reduction product of NOx in the presence of steam is NH3. The formation of NH3 is attributed the reaction between NOx and H2, with H2 stemming from water gas shift (CO as reductant) or steam reforming (HC as reductant). Catalysts operated in L-R cycle mode are more effective to reduce NOx into NH3 than catalysts operated only under rich conditions. Additional experiments showed that the combination of Pt-BaO/Al2O3 and Co2+ exchanged zeolite could effectively inhibit the NH3 formation in L-R cycle (L/R=60/20 sec). However, if operation under rich condition is prolonged to 60 seconds (L/R=60/60), the major product under rich condition is still NH3.