Authors
T.J. Toops,
D.B. Smith, W.S. Epling,
J.E. Parks,
W.P. Partridge
Publication
Applied Catalysis B: Environmental 58 (2005) 255–264.
Abstract
A multi-component NOx-trap catalyst consisting of Pt and K supported on
γ–Al2O3 was studied at 250 °C to determine the roles of the
individual catalyst components, to identify the adsorbing species during the lean capture cycle, and to assess the effects of H2O and CO2 on
NOx storage.
The Al2O3 support was shown to have NOx trapping capability with and
without Pt present (at 250 °C Pt/Al2O3 adsorbs
2.3 µmols NOx/m2).
NOx is primarily trapped on Al2O3 in the form of nitrates with
monodentate, chelating and bridged forms apparent in Diffuse Reflectance mid-Infrared Fourier
Transform Spectroscopy (DRIFTS) analysis.
The addition of K to the catalyst increases the
adsorption capacity to 6.2 µmols NOx/m2, and the primary storage form on K
is a free nitrate ion. Quantitative DRIFTS analysis shows that
12% of the nitrates on a Pt/K/Al2O3 catalyst are coordinated on the
Al2O3 support at saturation.
When 5% CO2 was included in a feed stream with 300 ppm NO and 12% O2, the amount
of K-based nitrate storage decreased by 45% after
1 h on stream due to the competition of adsorbed free nitrates with carboxylates for adsorption sites.
When 5% H2O was included in a feed
stream with 300 ppm NO and 12% O2, the amount of K-based nitrate storage decreased by only
16% after 1 h, but the Al2O3-based nitrates
decreased by 92%. Interestingly, with both 5% CO2 and 5% H2O in the feed, the
total storage only decreased by 11%, as the hydroxyl groups
generated on Al2O3 destabilized the K-CO2 bond; specifically,
H2O mitigates the NOx storage capacity losses associated with carboxylate
competition.
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