(361b) In-Situ Drifts Studies of Selective Catalytic Reduction of NO With C3H6 On Cu-Chabazite Catalyst
AIChE Annual Meeting
2013
2013 AIChE Annual Meeting
Catalysis and Reaction Engineering Division
Fundamentals of Environmental Catalysis
Tuesday, November 5, 2013 - 3:35pm to 3:55pm
In-situ DRIFTS Studies of Selective
Catalytic Reduction of NO with C3H6 on Cu-chabazite
Catalyst
Richa Raj, Michael P. Harold[1],
and Vemuri Balakotaiah[2]
Department of Chemical &
Biomolecular Engineering, University of Houston, Houston, TX, United States.
Abstract
In-situ
DRIFTS studies were carried out to elucidate the underlying mechanism of NOx
reduction with C3H6. In-situ DRIFTS was performed using a Nicolet Nexus 470
spectrometer, equipped with a small collector with a dual sample environmental
chamber (Thermo Fisher Scientific). The sample of catalyst powder was prepared
by scraping the washcoat off the monolith channels. The feed gas, at a total
flow rate of 50 cm3/min at STP, was mixed using Bronkhorst mass flow
controllers; and its composition, with all gases present, was 500 ppm C3H6,
500 ppm NO, 1% or 5% O2, 0 or 2.5% H2O balanced by He.
Before each experiment, the catalyst sample of 60 mg was treated with 5% O2
in He for 1 hour at 600oC.
Fig. 1 shows the evolution of
surface species with time for C3H6 + O2
reaction. The growth of the bands around 1550 cm -1 and 2900 cm-1
correspond to stretching of C-C and C-H bonds of adsorbed hydrocarbon species,
respectively. The broad band near 3060 cm-1 corresponds to vibration
of C-H bond of condensed aromatic rings. The growth of these bands with time
suggest the formation and accumulation of coke like species on the catalyst
surface formed via oligomerization of adsorbed C3H6
derived hydrocarbon species. The appearance of band at 1660 cm-1
corresponds to C=O stretching of acrolein like species. Similarly, the peak at
1450 cm-1 corresponds to adsorbed carboxylate species. Hence,
oxygenates are the intermediates in C3H6 oxidation. Fig. 2 shows the spectra obtained for
different times on introduction of NO in feed after exposure to C3H6
+ O2. On exposure to NO a new peak at 2250 cm-1 is
observed which is attributed to ?NCO species. There is increase in the peak
intensity corresponding to ?NCO species with time suggesting its accumulation on
the catalyst surface. It clearly indicates that N-containing hydrocarbon
species act as intermediate in NOx reduction with C3H6.
Figure
1 DRIFTS spectra obtained at different times upon Cu-SSZ13 exposure to 500 ppm C3H6
at 380 oC (500 ppm C3H6, 1% O2,
balanced by He)
Figure
2 Emergence of new peak upon exposure to 500 ppm NO after 45 minutes of
exposure to 500 ppm C3H6 at 380 oC (500 ppm C3H6,
500 ppm NO, 1% O2, balanced by He)
[1]Corresponding author: Tel.: +1
713 743 4322; Fax: +1 713 743 4323; Email: mharold@uh.edu (M. P. Harold)
[2]Corresponding author: Tel.: +1
713 743 4318; Fax: +1 713 743 4323; Email: bala@uh.edu (V. Balakotaiah)