Using degrees of rate control to improve selective n-butane oxidation over model MOF-encapsulated catalysts: sterically-constrained Ag sub(3)Pd(111)
Metal nanoparticles encapsulated within metal organic frameworks (MOFs) offer steric restrictions near the catalytic metal that can improve selectivity, much like in enzymes. A microkinetic model is developed for the regio-selective oxidation of n-butane to 1-butanol with O sub(2) over a model for M...
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Veröffentlicht in: | Faraday discussions 2016-07, Vol.188, p.21-38 |
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description | Metal nanoparticles encapsulated within metal organic frameworks (MOFs) offer steric restrictions near the catalytic metal that can improve selectivity, much like in enzymes. A microkinetic model is developed for the regio-selective oxidation of n-butane to 1-butanol with O sub(2) over a model for MOF-encapsulated bimetallic nanoparticles. The model consists of a Ag sub(3)Pd(111) surface decorated with a 2-atom-thick ring of (immobile) helium atoms which creates an artificial pore of similar size to that in common MOFs, which sterically constrains the adsorbed reaction intermediates. The kinetic parameters are based on energies calculated using density functional theory (DFT). The microkinetic model was analysed at 423 K to determine the dominant pathways and which species (adsorbed intermediates and transition states in the reaction mechanism) have energies that most sensitively affect the reaction rates to the different products, using degree-of-rate-control (DRC) analysis. This analysis revealed that activation of the C-H bond is assisted by adsorbed oxygen atoms, O*. Unfortunately, O* also abstracts H from adsorbed 1-butanol and butoxy as well, leading to butanal as the only significant product. This suggested to (1) add water to produce more OH*, thus inhibiting these undesired steps which produce OH*, and (2) eliminate most of the O sub(2) pressure to reduce the O* coverage, thus also inhibiting these steps. Combined with increasing butane pressure, this dramatically improved the 1-butanol selectivity (from 0 to 95%) and the rate (to 2 molecules per site per s). Moreover, 40% less O sub(2) was consumed per oxygen atom in the products. Under these conditions, a terminal H in butane is directly eliminated to the Pd site, and the resulting adsorbed butyl combines with OH* to give the desired 1-butanol. These results demonstrate that DRC analysis provides a powerful approach for optimizing catalytic process conditions, and that highly selectivity oxidation can sometimes be achieved by using a mixture of O sub(2) and H sub(2)O as the oxidant. This was further demonstrated by DRC analysis of a second microkinetic model based on a related but hypothetical catalyst, where the activation energies for two of the steps were modified. |
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A microkinetic model is developed for the regio-selective oxidation of n-butane to 1-butanol with O sub(2) over a model for MOF-encapsulated bimetallic nanoparticles. The model consists of a Ag sub(3)Pd(111) surface decorated with a 2-atom-thick ring of (immobile) helium atoms which creates an artificial pore of similar size to that in common MOFs, which sterically constrains the adsorbed reaction intermediates. The kinetic parameters are based on energies calculated using density functional theory (DFT). The microkinetic model was analysed at 423 K to determine the dominant pathways and which species (adsorbed intermediates and transition states in the reaction mechanism) have energies that most sensitively affect the reaction rates to the different products, using degree-of-rate-control (DRC) analysis. This analysis revealed that activation of the C-H bond is assisted by adsorbed oxygen atoms, O*. Unfortunately, O* also abstracts H from adsorbed 1-butanol and butoxy as well, leading to butanal as the only significant product. This suggested to (1) add water to produce more OH*, thus inhibiting these undesired steps which produce OH*, and (2) eliminate most of the O sub(2) pressure to reduce the O* coverage, thus also inhibiting these steps. Combined with increasing butane pressure, this dramatically improved the 1-butanol selectivity (from 0 to 95%) and the rate (to 2 molecules per site per s). Moreover, 40% less O sub(2) was consumed per oxygen atom in the products. Under these conditions, a terminal H in butane is directly eliminated to the Pd site, and the resulting adsorbed butyl combines with OH* to give the desired 1-butanol. These results demonstrate that DRC analysis provides a powerful approach for optimizing catalytic process conditions, and that highly selectivity oxidation can sometimes be achieved by using a mixture of O sub(2) and H sub(2)O as the oxidant. This was further demonstrated by DRC analysis of a second microkinetic model based on a related but hypothetical catalyst, where the activation energies for two of the steps were modified.</description><identifier>ISSN: 1359-6640</identifier><identifier>EISSN: 1364-5498</identifier><identifier>DOI: 10.1039/c5fd00198f</identifier><language>eng</language><subject>Butanes ; Catalysis ; Catalysts ; Energy use ; Mathematical models ; Oxidation ; Oxygen atoms ; Selectivity</subject><ispartof>Faraday discussions, 2016-07, Vol.188, p.21-38</ispartof><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>314,780,784,27924,27925</link.rule.ids></links><search><creatorcontrib>Dix, Sean T</creatorcontrib><creatorcontrib>Scott, Joseph K</creatorcontrib><creatorcontrib>Getman, Rachel B</creatorcontrib><creatorcontrib>Campbell, Charles T</creatorcontrib><title>Using degrees of rate control to improve selective n-butane oxidation over model MOF-encapsulated catalysts: sterically-constrained Ag sub(3)Pd(111)</title><title>Faraday discussions</title><description>Metal nanoparticles encapsulated within metal organic frameworks (MOFs) offer steric restrictions near the catalytic metal that can improve selectivity, much like in enzymes. A microkinetic model is developed for the regio-selective oxidation of n-butane to 1-butanol with O sub(2) over a model for MOF-encapsulated bimetallic nanoparticles. The model consists of a Ag sub(3)Pd(111) surface decorated with a 2-atom-thick ring of (immobile) helium atoms which creates an artificial pore of similar size to that in common MOFs, which sterically constrains the adsorbed reaction intermediates. The kinetic parameters are based on energies calculated using density functional theory (DFT). The microkinetic model was analysed at 423 K to determine the dominant pathways and which species (adsorbed intermediates and transition states in the reaction mechanism) have energies that most sensitively affect the reaction rates to the different products, using degree-of-rate-control (DRC) analysis. This analysis revealed that activation of the C-H bond is assisted by adsorbed oxygen atoms, O*. Unfortunately, O* also abstracts H from adsorbed 1-butanol and butoxy as well, leading to butanal as the only significant product. This suggested to (1) add water to produce more OH*, thus inhibiting these undesired steps which produce OH*, and (2) eliminate most of the O sub(2) pressure to reduce the O* coverage, thus also inhibiting these steps. Combined with increasing butane pressure, this dramatically improved the 1-butanol selectivity (from 0 to 95%) and the rate (to 2 molecules per site per s). Moreover, 40% less O sub(2) was consumed per oxygen atom in the products. Under these conditions, a terminal H in butane is directly eliminated to the Pd site, and the resulting adsorbed butyl combines with OH* to give the desired 1-butanol. These results demonstrate that DRC analysis provides a powerful approach for optimizing catalytic process conditions, and that highly selectivity oxidation can sometimes be achieved by using a mixture of O sub(2) and H sub(2)O as the oxidant. This was further demonstrated by DRC analysis of a second microkinetic model based on a related but hypothetical catalyst, where the activation energies for two of the steps were modified.</description><subject>Butanes</subject><subject>Catalysis</subject><subject>Catalysts</subject><subject>Energy use</subject><subject>Mathematical models</subject><subject>Oxidation</subject><subject>Oxygen atoms</subject><subject>Selectivity</subject><issn>1359-6640</issn><issn>1364-5498</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2016</creationdate><recordtype>article</recordtype><recordid>eNqVjk1OwzAUhC0EEuVnwwneMl0YbBKnCTuEqNggWMC6cu2XyMixi5-D6D04MK7EBVjNSPNpZhi7kuJairq_MWqwQsi-G47YQtZtw1XTd8cHr3reto04ZWdEH0KItqQL9vNOLoxgcUyIBHGApDOCiSGn6CFHcNMuxS8EQo8mu-IC385ZB4T47azOLgYoQIIpWvTw_LLmGIze0exLlQWjs_Z7ynQHlDE5o73f87JAOWkXCnE_As3bql6-2kpKubxgJ4P2hJd_es6q9ePbwxMvTz5npLyZHBn0vpyIM21kd6tU04nVqv4H-gtwUGEy</recordid><startdate>20160701</startdate><enddate>20160701</enddate><creator>Dix, Sean T</creator><creator>Scott, Joseph K</creator><creator>Getman, Rachel B</creator><creator>Campbell, Charles T</creator><scope>7SR</scope><scope>8BQ</scope><scope>8FD</scope><scope>JG9</scope></search><sort><creationdate>20160701</creationdate><title>Using degrees of rate control to improve selective n-butane oxidation over model MOF-encapsulated catalysts: sterically-constrained Ag sub(3)Pd(111)</title><author>Dix, Sean T ; Scott, Joseph K ; Getman, Rachel B ; Campbell, Charles T</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-proquest_miscellaneous_18255480773</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2016</creationdate><topic>Butanes</topic><topic>Catalysis</topic><topic>Catalysts</topic><topic>Energy use</topic><topic>Mathematical models</topic><topic>Oxidation</topic><topic>Oxygen atoms</topic><topic>Selectivity</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Dix, Sean T</creatorcontrib><creatorcontrib>Scott, Joseph K</creatorcontrib><creatorcontrib>Getman, Rachel B</creatorcontrib><creatorcontrib>Campbell, Charles T</creatorcontrib><collection>Engineered Materials Abstracts</collection><collection>METADEX</collection><collection>Technology Research Database</collection><collection>Materials Research Database</collection><jtitle>Faraday discussions</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Dix, Sean T</au><au>Scott, Joseph K</au><au>Getman, Rachel B</au><au>Campbell, Charles T</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Using degrees of rate control to improve selective n-butane oxidation over model MOF-encapsulated catalysts: sterically-constrained Ag sub(3)Pd(111)</atitle><jtitle>Faraday discussions</jtitle><date>2016-07-01</date><risdate>2016</risdate><volume>188</volume><spage>21</spage><epage>38</epage><pages>21-38</pages><issn>1359-6640</issn><eissn>1364-5498</eissn><abstract>Metal nanoparticles encapsulated within metal organic frameworks (MOFs) offer steric restrictions near the catalytic metal that can improve selectivity, much like in enzymes. A microkinetic model is developed for the regio-selective oxidation of n-butane to 1-butanol with O sub(2) over a model for MOF-encapsulated bimetallic nanoparticles. The model consists of a Ag sub(3)Pd(111) surface decorated with a 2-atom-thick ring of (immobile) helium atoms which creates an artificial pore of similar size to that in common MOFs, which sterically constrains the adsorbed reaction intermediates. The kinetic parameters are based on energies calculated using density functional theory (DFT). The microkinetic model was analysed at 423 K to determine the dominant pathways and which species (adsorbed intermediates and transition states in the reaction mechanism) have energies that most sensitively affect the reaction rates to the different products, using degree-of-rate-control (DRC) analysis. This analysis revealed that activation of the C-H bond is assisted by adsorbed oxygen atoms, O*. Unfortunately, O* also abstracts H from adsorbed 1-butanol and butoxy as well, leading to butanal as the only significant product. This suggested to (1) add water to produce more OH*, thus inhibiting these undesired steps which produce OH*, and (2) eliminate most of the O sub(2) pressure to reduce the O* coverage, thus also inhibiting these steps. Combined with increasing butane pressure, this dramatically improved the 1-butanol selectivity (from 0 to 95%) and the rate (to 2 molecules per site per s). Moreover, 40% less O sub(2) was consumed per oxygen atom in the products. Under these conditions, a terminal H in butane is directly eliminated to the Pd site, and the resulting adsorbed butyl combines with OH* to give the desired 1-butanol. These results demonstrate that DRC analysis provides a powerful approach for optimizing catalytic process conditions, and that highly selectivity oxidation can sometimes be achieved by using a mixture of O sub(2) and H sub(2)O as the oxidant. This was further demonstrated by DRC analysis of a second microkinetic model based on a related but hypothetical catalyst, where the activation energies for two of the steps were modified.</abstract><doi>10.1039/c5fd00198f</doi></addata></record> |
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subjects | Butanes Catalysis Catalysts Energy use Mathematical models Oxidation Oxygen atoms Selectivity |
title | Using degrees of rate control to improve selective n-butane oxidation over model MOF-encapsulated catalysts: sterically-constrained Ag sub(3)Pd(111) |
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