First-principles microkinetic simulations revealing the scaling relations and structure sensitivity of CO2 hydrogenation to C1 & C2 oxygenates on Pd surfaces

Hydrogenation of CO2 to methanol, ethanol and other oxygenates is an emerging attractive process in C1 chemistry but remains a great challenge not least because of the intrinsic inertness of CO2, difficulty in C–C bond coupling, and complexity in product distribution. Identifying the dominant reacti...

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Veröffentlicht in:	Catalysis science & technology 2021-07, Vol.11 (14), p.4866-4881
Hauptverfasser:	Ke, Jun, Yang-Dong, Wang, Chuan-Ming, Wang
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Sprache:	eng
Schlagworte:	Carbon dioxide Carbon monoxide Coupling Covalent bonds Density functional theory Design optimization Ethanol First principles Free energy Heat of formation Hydrogenation Palladium Reaction mechanisms
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container_title	Catalysis science & technology
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creator	Ke, Jun Yang-Dong, Wang Chuan-Ming, Wang
description	Hydrogenation of CO2 to methanol, ethanol and other oxygenates is an emerging attractive process in C1 chemistry but remains a great challenge not least because of the intrinsic inertness of CO2, difficulty in C–C bond coupling, and complexity in product distribution. Identifying the dominant reaction mechanism is therefore urgent but still lacking under real reaction conditions. In this work, by combining density functional theory calculations with microkinetic modeling, we predicted the activity plots of C1 & C2 oxygenates as a function of temperature and pressure on both stepped Pd(211) and flat Pd(111) surfaces according to the reaction network consisting of ∼150 elementary steps. We found that Pd(211) is more active than Pd(111), and the incremental effect is more remarkable for the production of C2 oxygenates. An optimal reaction temperature of around 500 K is theoretically rationalized. COOH is the key intermediate in CO2 activation, and the CO insertion with CHx highly contributes to the C–C bond coupling. Formation of ethanol is directly competitive with that of methane. The activity dependences on reaction conditions are different between CO2 and CO hydrogenation. The formation energy scaling relations of intermediates and transition states between the different Pd surfaces were established, providing a simplified strategy to estimate transition state energies on other surfaces for microkinetic simulation. All these constitute the key foundation for the rational design of metal catalysts and optimization of reaction conditions for CO2 hydrogenation to C1 & C2 oxygenates.
doi_str_mv	10.1039/d1cy00700a
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Identifying the dominant reaction mechanism is therefore urgent but still lacking under real reaction conditions. In this work, by combining density functional theory calculations with microkinetic modeling, we predicted the activity plots of C1 & C2 oxygenates as a function of temperature and pressure on both stepped Pd(211) and flat Pd(111) surfaces according to the reaction network consisting of ∼150 elementary steps. We found that Pd(211) is more active than Pd(111), and the incremental effect is more remarkable for the production of C2 oxygenates. An optimal reaction temperature of around 500 K is theoretically rationalized. COOH is the key intermediate in CO2 activation, and the CO insertion with CHx highly contributes to the C–C bond coupling. Formation of ethanol is directly competitive with that of methane. The activity dependences on reaction conditions are different between CO2 and CO hydrogenation. The formation energy scaling relations of intermediates and transition states between the different Pd surfaces were established, providing a simplified strategy to estimate transition state energies on other surfaces for microkinetic simulation. All these constitute the key foundation for the rational design of metal catalysts and optimization of reaction conditions for CO2 hydrogenation to C1 & C2 oxygenates.</description><identifier>ISSN: 2044-4753</identifier><identifier>EISSN: 2044-4761</identifier><identifier>DOI: 10.1039/d1cy00700a</identifier><language>eng</language><publisher>Cambridge: Royal Society of Chemistry</publisher><subject>Carbon dioxide ; Carbon monoxide ; Coupling ; Covalent bonds ; Density functional theory ; Design optimization ; Ethanol ; First principles ; Free energy ; Heat of formation ; Hydrogenation ; Palladium ; Reaction mechanisms</subject><ispartof>Catalysis science & technology, 2021-07, Vol.11 (14), p.4866-4881</ispartof><rights>Copyright Royal Society of Chemistry 2021</rights><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>314,778,782,27911,27912</link.rule.ids></links><search><creatorcontrib>Ke, Jun</creatorcontrib><creatorcontrib>Yang-Dong, Wang</creatorcontrib><creatorcontrib>Chuan-Ming, Wang</creatorcontrib><title>First-principles microkinetic simulations revealing the scaling relations and structure sensitivity of CO2 hydrogenation to C1 & C2 oxygenates on Pd surfaces</title><title>Catalysis science & technology</title><description>Hydrogenation of CO2 to methanol, ethanol and other oxygenates is an emerging attractive process in C1 chemistry but remains a great challenge not least because of the intrinsic inertness of CO2, difficulty in C–C bond coupling, and complexity in product distribution. 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The formation energy scaling relations of intermediates and transition states between the different Pd surfaces were established, providing a simplified strategy to estimate transition state energies on other surfaces for microkinetic simulation. 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Identifying the dominant reaction mechanism is therefore urgent but still lacking under real reaction conditions. In this work, by combining density functional theory calculations with microkinetic modeling, we predicted the activity plots of C1 & C2 oxygenates as a function of temperature and pressure on both stepped Pd(211) and flat Pd(111) surfaces according to the reaction network consisting of ∼150 elementary steps. We found that Pd(211) is more active than Pd(111), and the incremental effect is more remarkable for the production of C2 oxygenates. An optimal reaction temperature of around 500 K is theoretically rationalized. COOH is the key intermediate in CO2 activation, and the CO insertion with CHx highly contributes to the C–C bond coupling. Formation of ethanol is directly competitive with that of methane. The activity dependences on reaction conditions are different between CO2 and CO hydrogenation. 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subjects	Carbon dioxide Carbon monoxide Coupling Covalent bonds Density functional theory Design optimization Ethanol First principles Free energy Heat of formation Hydrogenation Palladium Reaction mechanisms
title	First-principles microkinetic simulations revealing the scaling relations and structure sensitivity of CO2 hydrogenation to C1 & C2 oxygenates on Pd surfaces
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