Understanding the Synergistic Catalytic Effect between La2O3 and CaO for the CH4 Lean De-NO x Reaction: Kinetic and Mechanistic Studies

Doping of La2O3 crystallites with Ca2+ ions significantly enhances the intrinsic rate of NO reduction by CH4 in the presence of 5% O2 at 550 °C compared to pure La2O3 and CaO solids, while the opposite is true after doping of CaO with La3+ ions. It was found that the 5 wt % La2O3−95 wt % CaO system...

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Veröffentlicht in:	The journal of physical chemistry. B 2005-07, Vol.109 (28), p.13693-13703
Hauptverfasser:	Anastasiadou, T, Loukatzikou, L. A, Costa, C. N, Efstathiou, A. M
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creator	Anastasiadou, T Loukatzikou, L. A Costa, C. N Efstathiou, A. M
description	Doping of La2O3 crystallites with Ca2+ ions significantly enhances the intrinsic rate of NO reduction by CH4 in the presence of 5% O2 at 550 °C compared to pure La2O3 and CaO solids, while the opposite is true after doping of CaO with La3+ ions. It was found that the 5 wt % La2O3−95 wt % CaO system has one of the highest intrinsic site reactivities (TOF = 8.5 × 10-3 s-1) reported at 550 °C for the NO/CH4/O2 reaction among metal oxide surfaces. The doping process occurred after first dispersing La2O3 and CaO crystallites in deionized water heated to 60 °C for 90 min, while the dried material was then ground and heated slowly in air to 800 °C and kept at this temperature for 5 h. The doping process had the effect of creating surface oxygen vacant sites (F-type defects) in the oxide lattices the concentration of which is a function of the wt % La2O3 used in the mixed oxide system as revealed by photoluminescence and O2 chemisorption studies. According to DRIFTS 15NO transient isotopic experiments (SSITKA), oxygen vacant sites in Ca2+-doped La2O3 promote the formation of a more active chemisorbed NO x species (NO2 -) that contributes to the enhancement of reaction rate as compared to pure lanthana, calcium oxide, and La3+-doped CaO. These results were supported by the kinetic orders of the reaction with respect to NO and O2 obtained as a function of wt % La2O3 content in the mixed oxide system. Carbon dioxide (a reaction product) competes for the same oxygen vacant sites to form stable adsorbed carbonate-like species, thus lowering the reduction rate of NO. The dependence of the reaction TOF on the wt % La2O3 loading at 550 °C was found to follow the trend of the dependence of photoluminescence intensity on the wt % La2O3 content in the La2O3−CaO oxide system.
doi_str_mv	10.1021/jp0515582
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N ; Efstathiou, A. M</creator><creatorcontrib>Anastasiadou, T ; Loukatzikou, L. A ; Costa, C. N ; Efstathiou, A. M</creatorcontrib><description>Doping of La2O3 crystallites with Ca2+ ions significantly enhances the intrinsic rate of NO reduction by CH4 in the presence of 5% O2 at 550 °C compared to pure La2O3 and CaO solids, while the opposite is true after doping of CaO with La3+ ions. It was found that the 5 wt % La2O3−95 wt % CaO system has one of the highest intrinsic site reactivities (TOF = 8.5 × 10-3 s-1) reported at 550 °C for the NO/CH4/O2 reaction among metal oxide surfaces. The doping process occurred after first dispersing La2O3 and CaO crystallites in deionized water heated to 60 °C for 90 min, while the dried material was then ground and heated slowly in air to 800 °C and kept at this temperature for 5 h. The doping process had the effect of creating surface oxygen vacant sites (F-type defects) in the oxide lattices the concentration of which is a function of the wt % La2O3 used in the mixed oxide system as revealed by photoluminescence and O2 chemisorption studies. According to DRIFTS 15NO transient isotopic experiments (SSITKA), oxygen vacant sites in Ca2+-doped La2O3 promote the formation of a more active chemisorbed NO x species (NO2 -) that contributes to the enhancement of reaction rate as compared to pure lanthana, calcium oxide, and La3+-doped CaO. These results were supported by the kinetic orders of the reaction with respect to NO and O2 obtained as a function of wt % La2O3 content in the mixed oxide system. Carbon dioxide (a reaction product) competes for the same oxygen vacant sites to form stable adsorbed carbonate-like species, thus lowering the reduction rate of NO. The dependence of the reaction TOF on the wt % La2O3 loading at 550 °C was found to follow the trend of the dependence of photoluminescence intensity on the wt % La2O3 content in the La2O3−CaO oxide system.</description><identifier>ISSN: 1520-6106</identifier><identifier>EISSN: 1520-5207</identifier><identifier>DOI: 10.1021/jp0515582</identifier><language>eng</language><publisher>American Chemical Society</publisher><ispartof>The journal of physical chemistry. 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The doping process had the effect of creating surface oxygen vacant sites (F-type defects) in the oxide lattices the concentration of which is a function of the wt % La2O3 used in the mixed oxide system as revealed by photoluminescence and O2 chemisorption studies. According to DRIFTS 15NO transient isotopic experiments (SSITKA), oxygen vacant sites in Ca2+-doped La2O3 promote the formation of a more active chemisorbed NO x species (NO2 -) that contributes to the enhancement of reaction rate as compared to pure lanthana, calcium oxide, and La3+-doped CaO. These results were supported by the kinetic orders of the reaction with respect to NO and O2 obtained as a function of wt % La2O3 content in the mixed oxide system. Carbon dioxide (a reaction product) competes for the same oxygen vacant sites to form stable adsorbed carbonate-like species, thus lowering the reduction rate of NO. 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M</creator><general>American Chemical Society</general><scope/></search><sort><creationdate>20050721</creationdate><title>Understanding the Synergistic Catalytic Effect between La2O3 and CaO for the CH4 Lean De-NO x Reaction: Kinetic and Mechanistic Studies</title><author>Anastasiadou, T ; Loukatzikou, L. A ; Costa, C. N ; Efstathiou, A. M</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-acs_journals_10_1021_jp05155823</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2005</creationdate><toplevel>online_resources</toplevel><creatorcontrib>Anastasiadou, T</creatorcontrib><creatorcontrib>Loukatzikou, L. A</creatorcontrib><creatorcontrib>Costa, C. N</creatorcontrib><creatorcontrib>Efstathiou, A. M</creatorcontrib><jtitle>The journal of physical chemistry. 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It was found that the 5 wt % La2O3−95 wt % CaO system has one of the highest intrinsic site reactivities (TOF = 8.5 × 10-3 s-1) reported at 550 °C for the NO/CH4/O2 reaction among metal oxide surfaces. The doping process occurred after first dispersing La2O3 and CaO crystallites in deionized water heated to 60 °C for 90 min, while the dried material was then ground and heated slowly in air to 800 °C and kept at this temperature for 5 h. The doping process had the effect of creating surface oxygen vacant sites (F-type defects) in the oxide lattices the concentration of which is a function of the wt % La2O3 used in the mixed oxide system as revealed by photoluminescence and O2 chemisorption studies. According to DRIFTS 15NO transient isotopic experiments (SSITKA), oxygen vacant sites in Ca2+-doped La2O3 promote the formation of a more active chemisorbed NO x species (NO2 -) that contributes to the enhancement of reaction rate as compared to pure lanthana, calcium oxide, and La3+-doped CaO. These results were supported by the kinetic orders of the reaction with respect to NO and O2 obtained as a function of wt % La2O3 content in the mixed oxide system. Carbon dioxide (a reaction product) competes for the same oxygen vacant sites to form stable adsorbed carbonate-like species, thus lowering the reduction rate of NO. The dependence of the reaction TOF on the wt % La2O3 loading at 550 °C was found to follow the trend of the dependence of photoluminescence intensity on the wt % La2O3 content in the La2O3−CaO oxide system.</abstract><pub>American Chemical Society</pub><doi>10.1021/jp0515582</doi></addata></record>
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title	Understanding the Synergistic Catalytic Effect between La2O3 and CaO for the CH4 Lean De-NO x Reaction: Kinetic and Mechanistic Studies
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