Step enhanced dehydrogenation of ethanol on Rh

Resta, Andrea; Gustafson, Johan; Westerström, Rasmus; Mikkelsen, Anders; Lundgren, Edvin; Andersen, Jesper N; Yang, Ming-Mei; Ma, Xiu-Fang; Bao, Xin-He; Li, Wei-Xue

Step enhanced dehydrogenation of ethanol on Rh

Mark

Resta, Andrea ^LU ; Gustafson, Johan ^LU ; Westerström, Rasmus ^LU ; Mikkelsen, Anders ^LU ; Lundgren, Edvin ^LU ; Andersen, Jesper N ^LU ; Yang, Ming-Mei ; Ma, Xiu-Fang ; Bao, Xin-He and Li, Wei-Xue (2008) In Surface Science 602(18). p.3057-3063

Abstract: We have investigated the adsorption and decomposition of ethanol on the Rh(111) and Rh(5 5 3) surfaces at room temperature with special emphasis on the dehydrogenation. We use high resolution Core level photoemission and density functional theory (DFT) based simulations. A detailed analysis of the C1s core level spectra, including analysis of the vibrational fine-structure and comparison to calculated C1s binding energy shifts, shows that the ethanol decomposes into CO, ethylidyne (C2H3) methylidyne (CH), atomic C, and hydrogen. At low ethanol exposures, CH is the dominating hydrocarbon fragment on Rh(111), whereas on Rh(553) atomic C dominates over CH, indicating an enhanced dehydrogenation due to the steps present on the latter surface.... (More); We have investigated the adsorption and decomposition of ethanol on the Rh(111) and Rh(5 5 3) surfaces at room temperature with special emphasis on the dehydrogenation. We use high resolution Core level photoemission and density functional theory (DFT) based simulations. A detailed analysis of the C1s core level spectra, including analysis of the vibrational fine-structure and comparison to calculated C1s binding energy shifts, shows that the ethanol decomposes into CO, ethylidyne (C2H3) methylidyne (CH), atomic C, and hydrogen. At low ethanol exposures, CH is the dominating hydrocarbon fragment on Rh(111), whereas on Rh(553) atomic C dominates over CH, indicating an enhanced dehydrogenation due to the steps present on the latter surface. At higher ethanol exposures we find a similar behavior of atomic C dominating over hydrocarbons on Rh(553), while on Rh(111) atomic carbon remains a minority species. Our DFT based simulations show that the enhanced dehydrogenation results from a significant lowering of the CH dissociation barrier from Rh(111) to Rh(553), as well as from the dissociation changing from endothermic on Rh(111) to exothermic on Rh(553). (C) 2008 Elsevier B.V. All rights reserved. (Less)

Please use this url to cite or link to this publication: https://lup.lub.lu.se/record/1278941

author

Resta, Andrea ^LU ; Gustafson, Johan ^LU ; Westerström, Rasmus ^LU ; Mikkelsen, Anders ^LU ; Lundgren, Edvin ^LU ; Andersen, Jesper N ^LU ; Yang, Ming-Mei ; Ma, Xiu-Fang ; Bao, Xin-He and Li, Wei-Xue

organization

Synchrotron Radiation Research

publishing date

2008

type

Contribution to journal

publication status

published

subject

Atom and Molecular Physics and Optics

keywords

spectroscopy, synchrotron radiation photoelectron, photoelectron spectroscopy, Density functional calculations, soft X-ray, Photoelectron spectroscopy, Surface chemical reaction, Catalysis, Chemisorption, Rh, H, CO, C, ethylidyne, methylidyne, ethanol

in

Surface Science

volume

602

issue

18

pages

3057 - 3063

publisher

Elsevier

external identifiers

wos:000260550500018
scopus:52049099349

ISSN

0039-6028

DOI

10.1016/j.susc.2008.08.004

language

English

LU publication?

yes

id

7fa5692a-6e22-4e61-80dd-1708df931e07 (old id 1278941)

date added to LUP

2016-04-01 14:16:20

date last changed

2022-04-22 02:18:12

@article{7fa5692a-6e22-4e61-80dd-1708df931e07,
  abstract     = {{We have investigated the adsorption and decomposition of ethanol on the Rh(111) and Rh(5 5 3) surfaces at room temperature with special emphasis on the dehydrogenation. We use high resolution Core level photoemission and density functional theory (DFT) based simulations. A detailed analysis of the C1s core level spectra, including analysis of the vibrational fine-structure and comparison to calculated C1s binding energy shifts, shows that the ethanol decomposes into CO, ethylidyne (C2H3) methylidyne (CH), atomic C, and hydrogen. At low ethanol exposures, CH is the dominating hydrocarbon fragment on Rh(111), whereas on Rh(553) atomic C dominates over CH, indicating an enhanced dehydrogenation due to the steps present on the latter surface. At higher ethanol exposures we find a similar behavior of atomic C dominating over hydrocarbons on Rh(553), while on Rh(111) atomic carbon remains a minority species. Our DFT based simulations show that the enhanced dehydrogenation results from a significant lowering of the CH dissociation barrier from Rh(111) to Rh(553), as well as from the dissociation changing from endothermic on Rh(111) to exothermic on Rh(553). (C) 2008 Elsevier B.V. All rights reserved.}},
  author       = {{Resta, Andrea and Gustafson, Johan and Westerström, Rasmus and Mikkelsen, Anders and Lundgren, Edvin and Andersen, Jesper N and Yang, Ming-Mei and Ma, Xiu-Fang and Bao, Xin-He and Li, Wei-Xue}},
  issn         = {{0039-6028}},
  keywords     = {{spectroscopy; synchrotron radiation photoelectron; photoelectron spectroscopy; Density functional calculations; soft X-ray; Photoelectron spectroscopy; Surface chemical reaction; Catalysis; Chemisorption; Rh; H; CO; C; ethylidyne; methylidyne; ethanol}},
  language     = {{eng}},
  number       = {{18}},
  pages        = {{3057--3063}},
  publisher    = {{Elsevier}},
  series       = {{Surface Science}},
  title        = {{Step enhanced dehydrogenation of ethanol on Rh}},
  url          = {{http://dx.doi.org/10.1016/j.susc.2008.08.004}},
  doi          = {{10.1016/j.susc.2008.08.004}},
  volume       = {{602}},
  year         = {{2008}},
}

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Step enhanced dehydrogenation of ethanol on Rh