Identifying critical factors in the regeneration of NO sub(x)-trap materials under realistic conditions using fast transient techniques

NO sub(x) storage and reduction (NSR) catalysts are considered to be one of the most promising solutions to meet the upcoming NO sub(x) exhaust emission regulations. However, despite the high level of activity in this area, it is surprising that most studies have been conducted under conditions that...

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Bibliographic Details
Published in:Applied catalysis. B, Environmental Environmental, 2007-03, Vol.72 (1-2), p.178-186
Main Authors: Breen, J P, Rioche, C, Burch, R, Hardacre, C, Meunier, F C
Format: Article
Language:English
Subjects:
Catalysis
Catalysts
Exhaust emissions
Hydrogen
low temperature
Q1
regeneration
Storage
Temperature
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Summary:NO sub(x) storage and reduction (NSR) catalysts are considered to be one of the most promising solutions to meet the upcoming NO sub(x) exhaust emission regulations. However, despite the high level of activity in this area, it is surprising that most studies have been conducted under conditions that are far from realistic conditions. In the present work a fast transient apparatus has been developed to study NSR catalysts under realistic temporal conditions, i.e. where the storage time was 1-2 min and the regenerative rich time was of the order of 1 s. To exemplify the value of this methodology, the performance of a 1%Pt/17.5%Ba/ gamma -Al sub(2)O sub(3) NSR catalyst was studied as a function of the temperature, rich phase duration, reductant concentration, the type of reductant and the effect of an inert gas purge. From these results it is clearly found that excess reductant to regenerate the trap at short regeneration times is advantageous and that hydrogen is a better reductant than CO. This is especially true at low temperatures where the rate of reduction of released NO sub(x) is not sufficiently fast to allow for complete regeneration of the trap. For a given quantity of reductant, a long, low concentration rich pulse regenerates the catalyst more effectively than a short, high concentration pulse. Readsorption of NO sub(x) released during the rich phase but not reduced quickly enough can be a significant cause of loss of trap performance. This study underlines the importance of the regeneration step in the NSR process and highlights the need to investigate these systems using fast transient techniques capable of reproducing the short regeneration times used in real systems.
ISSN:0926-3373
DOI:10.1016/j.apcatb.2006.11.002