Quantum-Chemical DFT Study of Direct and H- and C-Assisted CO Dissociation on the χ-Fe(5)C(2) Hägg Carbide

[Image: see text] The first step in the Fischer–Tropsch reaction is the production of C(1) monomers by the dissociation of the C–O bond. Although Fe is the active metal, it is well known that under typical reaction conditions, it changes into various carbide phases. The Hägg carbide (χ-Fe(5)C(2)) ph...

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Autores principales: Broos, Robin J. P., Zijlstra, Bart, Filot, Ivo A. W., Hensen, Emiel J. M.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: American Chemical Society 2018
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5949720/
https://www.ncbi.nlm.nih.gov/pubmed/29774085
http://dx.doi.org/10.1021/acs.jpcc.8b01064
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author Broos, Robin J. P.
Zijlstra, Bart
Filot, Ivo A. W.
Hensen, Emiel J. M.
author_facet Broos, Robin J. P.
Zijlstra, Bart
Filot, Ivo A. W.
Hensen, Emiel J. M.
author_sort Broos, Robin J. P.
collection PubMed
description [Image: see text] The first step in the Fischer–Tropsch reaction is the production of C(1) monomers by the dissociation of the C–O bond. Although Fe is the active metal, it is well known that under typical reaction conditions, it changes into various carbide phases. The Hägg carbide (χ-Fe(5)C(2)) phase is usually considered as the catalytically active phase. We carried out a comprehensive DFT study of CO dissociation on various surface terminations of the Hägg carbide, selected on their specific site topology and the presence of stepped sites. Based on the reaction energetics, we identified several feasible CO dissociation pathways over the Hägg carbide. In this study, we have compared the direct CO dissociation with H- and C-assisted CO dissociation mechanisms. We demonstrated that the reaction rate for CO dissociation critically depends on the presence and topology of interstitial C atoms close to the active site. Typically, the CO dissociation proceeds via a direct C–O bond scission mechanism on the stepped sites on the Fe carbide surface. We have shown a preference for the direct CO dissociation on the surfaces with a stepped character. The H-assisted CO dissociation, via a CHO intermediate, was preferred when the surface did not have a clear stepped character. We have also shown that activation barriers for dissociation are highly dependent on the surface termination. With a consistent data set and including migration corrections, we then compared the CO dissociation rates based on a simplified kinetic model. With this model, we showed that besides the activation energy, the adsorption energy of the CO, the C and the O species are important for the reaction rate as well. We found that the most active surface termination is a (111̅) surface cut in such a way that the surface exposes B(5) sites that are not occupied by the C atoms. On these B(5) sites, the direct CO dissociation presents the highest rate.
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spelling pubmed-59497202018-05-15 Quantum-Chemical DFT Study of Direct and H- and C-Assisted CO Dissociation on the χ-Fe(5)C(2) Hägg Carbide Broos, Robin J. P. Zijlstra, Bart Filot, Ivo A. W. Hensen, Emiel J. M. J Phys Chem C Nanomater Interfaces [Image: see text] The first step in the Fischer–Tropsch reaction is the production of C(1) monomers by the dissociation of the C–O bond. Although Fe is the active metal, it is well known that under typical reaction conditions, it changes into various carbide phases. The Hägg carbide (χ-Fe(5)C(2)) phase is usually considered as the catalytically active phase. We carried out a comprehensive DFT study of CO dissociation on various surface terminations of the Hägg carbide, selected on their specific site topology and the presence of stepped sites. Based on the reaction energetics, we identified several feasible CO dissociation pathways over the Hägg carbide. In this study, we have compared the direct CO dissociation with H- and C-assisted CO dissociation mechanisms. We demonstrated that the reaction rate for CO dissociation critically depends on the presence and topology of interstitial C atoms close to the active site. Typically, the CO dissociation proceeds via a direct C–O bond scission mechanism on the stepped sites on the Fe carbide surface. We have shown a preference for the direct CO dissociation on the surfaces with a stepped character. The H-assisted CO dissociation, via a CHO intermediate, was preferred when the surface did not have a clear stepped character. We have also shown that activation barriers for dissociation are highly dependent on the surface termination. With a consistent data set and including migration corrections, we then compared the CO dissociation rates based on a simplified kinetic model. With this model, we showed that besides the activation energy, the adsorption energy of the CO, the C and the O species are important for the reaction rate as well. We found that the most active surface termination is a (111̅) surface cut in such a way that the surface exposes B(5) sites that are not occupied by the C atoms. On these B(5) sites, the direct CO dissociation presents the highest rate. American Chemical Society 2018-03-18 2018-05-10 /pmc/articles/PMC5949720/ /pubmed/29774085 http://dx.doi.org/10.1021/acs.jpcc.8b01064 Text en Copyright © 2018 American Chemical Society This is an open access article published under a Creative Commons Non-Commercial No Derivative Works (CC-BY-NC-ND) Attribution License (http://pubs.acs.org/page/policy/authorchoice_ccbyncnd_termsofuse.html) , which permits copying and redistribution of the article, and creation of adaptations, all for non-commercial purposes.
spellingShingle Broos, Robin J. P.
Zijlstra, Bart
Filot, Ivo A. W.
Hensen, Emiel J. M.
Quantum-Chemical DFT Study of Direct and H- and C-Assisted CO Dissociation on the χ-Fe(5)C(2) Hägg Carbide
title Quantum-Chemical DFT Study of Direct and H- and C-Assisted CO Dissociation on the χ-Fe(5)C(2) Hägg Carbide
title_full Quantum-Chemical DFT Study of Direct and H- and C-Assisted CO Dissociation on the χ-Fe(5)C(2) Hägg Carbide
title_fullStr Quantum-Chemical DFT Study of Direct and H- and C-Assisted CO Dissociation on the χ-Fe(5)C(2) Hägg Carbide
title_full_unstemmed Quantum-Chemical DFT Study of Direct and H- and C-Assisted CO Dissociation on the χ-Fe(5)C(2) Hägg Carbide
title_short Quantum-Chemical DFT Study of Direct and H- and C-Assisted CO Dissociation on the χ-Fe(5)C(2) Hägg Carbide
title_sort quantum-chemical dft study of direct and h- and c-assisted co dissociation on the χ-fe(5)c(2) hägg carbide
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5949720/
https://www.ncbi.nlm.nih.gov/pubmed/29774085
http://dx.doi.org/10.1021/acs.jpcc.8b01064
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