The selective catalytic reduction of nitric oxide by propylene over bimetallic CeO2-ZrO2 supported catalyst
Air pollution by nitrogen oxides (NOx) is currently one of the most serious environmental problems. The conventional three-way catalyst shows low NOx conversion in lean burn exhaust that contains high concentration of O2. The selective catalytic reduction of NO (SCR-NO) with C3H6 in the presence...
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| Main Author: | |
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| Format: | Thesis |
| Language: | English |
| Published: |
2005
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| Subjects: | |
| Online Access: | http://eprints.utm.my/id/eprint/4353/1/ChongCheeMingMFChE2005.pdf http://eprints.utm.my/id/eprint/4353/ |
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| Institution: | Universiti Teknologi Malaysia |
| Language: | English |
| Summary: | Air pollution by nitrogen oxides (NOx) is currently one of the most serious
environmental problems. The conventional three-way catalyst shows low NOx
conversion in lean burn exhaust that contains high concentration of O2. The selective
catalytic reduction of NO (SCR-NO) with C3H6 in the presence of excess O2 over
bimetallic Cu-Ag catalysts supported on CeO2-ZrO2 was investigated in this study.
Initially, it was found that the loading of Ag strongly promoted the catalytic
performance of Cu(4)/CeO2 catalyst, reaching a maximum NO conversion with the
doping of 1 wt% Ag. The UV-Vis DRS results revealed that the major species on
Cu(4)/Ag(1)/CeO2 catalyst were isolated Cu2+ species and Agn
􀄯+ clusters which are
responsible toward a higher NO reduction activity. However, Cu(4)/Ag(1)/CeO2
catalyst is not a promising catalyst for practical use due to its low activity in the
temperature region of 250-350ºC. Extended studies were conducted to investigate
the influence of different supports on the activity of SCR-NO.
Cu(4)/Ag(1)/CeO2(75)-ZrO2(25) catalyst was observed to demonstrate higher NO
conversions at low temperature region than the Cu(4)/Ag(1)/CeO2 catalyst due to its
strong metal-support interaction and high reducibility. It is presumed that these
features would enhance the activation of C3H6 to selectively react with NO at low
temperature region. Central composite design coupled with response surface
methodology was employed to study the effect of operating variables on the SCR
activity of Cu(4)/Ag(1)/CeO2(75)-ZrO2(25) catalyst and to determine the optimum
NO conversion. The ranges of the temperature, NO concentration and C3H6
concentration used in this study were 224-576ºC, 818-2582 ppm and 818-2582 ppm ,
respectively as determined by the central composite design. The optimum NO
conversion of 82.89% was obtained at 415.38ºC, 1827.16 ppm of NO concentration
and 1908.13 ppm of C3H6 concentration. A Langmuir-Hinshelwood kinetic model
was proposed for this study over Cu(4)/Ag(1)/CeO2(75)-ZrO2(25) catalyst.
Prediction from the model agreed well with the experimental results. The model
indicated that the surface reaction between adsorbed NOx species and partially
oxidized hydrocarbon was the rate-limiting step for this process. |
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