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Adsorption of formate species on Cu(h,k,l) low index surfaces

Adsorption of formate species on Cu(h,k,l) low index surfaces
Adsorption of formate species on Cu(h,k,l) low index surfaces
We report a density functional theory study on the relative stability of formate species on Cu(h,k,l) low index surfaces using a range of exchange-correlation functionals. We find that these functionals predict similar geometries for the formate molecule adsorbed on the Cu surface. A comparison of the calculated vibrational transition energies of a perpendicular configuration of formate on Cu surface shows an excellent agreement with the experimental spectrum obtained from inelastic neutron spectroscopy. From the calculations on adsorption energy we find that formate is most stable on the Cu(110) surface as compared to Cu(111) and Cu(100) surfaces. Bader analysis shows that this feature could be related to the higher charge transfer from the Cu(110) surface and optimum charge density at the interfacial region due to bidirectional electron transfer between the formate and the Cu surface. Analysis of the partial density of states finds that in the –5.5 eV to –4.0 eV region, hybridization between O p and the non-axial Cu dyz and dxz orbitals takes place on the Cu(110) surface, which is energetically more favourable than on the other surfaces.
0039-6028
45-54
Chutia, Arunabhiram
fe207bfe-0a7e-4369-8e62-bfa575399f83
Silverwood, Ian P.
82866f8b-db54-4b52-ae0e-20ac70e21b9e
Farrow, Matthew R.
127f0b6e-22b0-43f4-a537-0ae1609da687
Scanlon, David O.
23dbcc36-0b42-40dc-a3af-64c8bad7beb3
Wells, Peter
bc4fdc2d-a490-41bf-86cc-400edecf2266
Bowker, Michael
c9ab10a5-d144-4533-bf6d-2fa16b669565
Parker, Stewart F.
8752cd59-1b63-4399-859d-78e11a37c6d4
Catlow, C. Richard A.
50b88125-9415-4b37-9146-af6783e42510
Chutia, Arunabhiram
fe207bfe-0a7e-4369-8e62-bfa575399f83
Silverwood, Ian P.
82866f8b-db54-4b52-ae0e-20ac70e21b9e
Farrow, Matthew R.
127f0b6e-22b0-43f4-a537-0ae1609da687
Scanlon, David O.
23dbcc36-0b42-40dc-a3af-64c8bad7beb3
Wells, Peter
bc4fdc2d-a490-41bf-86cc-400edecf2266
Bowker, Michael
c9ab10a5-d144-4533-bf6d-2fa16b669565
Parker, Stewart F.
8752cd59-1b63-4399-859d-78e11a37c6d4
Catlow, C. Richard A.
50b88125-9415-4b37-9146-af6783e42510

Chutia, Arunabhiram, Silverwood, Ian P., Farrow, Matthew R., Scanlon, David O., Wells, Peter, Bowker, Michael, Parker, Stewart F. and Catlow, C. Richard A. (2016) Adsorption of formate species on Cu(h,k,l) low index surfaces. Surface Science, 653, 45-54. (doi:10.1016/j.susc.2016.05.002).

Record type: Article

Abstract

We report a density functional theory study on the relative stability of formate species on Cu(h,k,l) low index surfaces using a range of exchange-correlation functionals. We find that these functionals predict similar geometries for the formate molecule adsorbed on the Cu surface. A comparison of the calculated vibrational transition energies of a perpendicular configuration of formate on Cu surface shows an excellent agreement with the experimental spectrum obtained from inelastic neutron spectroscopy. From the calculations on adsorption energy we find that formate is most stable on the Cu(110) surface as compared to Cu(111) and Cu(100) surfaces. Bader analysis shows that this feature could be related to the higher charge transfer from the Cu(110) surface and optimum charge density at the interfacial region due to bidirectional electron transfer between the formate and the Cu surface. Analysis of the partial density of states finds that in the –5.5 eV to –4.0 eV region, hybridization between O p and the non-axial Cu dyz and dxz orbitals takes place on the Cu(110) surface, which is energetically more favourable than on the other surfaces.

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Accepted/In Press date: 5 May 2016
e-pub ahead of print date: 7 May 2016
Published date: November 2016
Organisations: Organic Chemistry: SCF

Identifiers

Local EPrints ID: 402204
URI: http://eprints.soton.ac.uk/id/eprint/402204
DOI: doi:10.1016/j.susc.2016.05.002
ISSN: 0039-6028
PURE UUID: abb8eda1-b008-4d29-9291-542d695f7e1e
ORCID for Peter Wells: ORCID iD orcid.org/0000-0002-0859-9172

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Date deposited: 03 Nov 2016 15:01
Last modified: 15 Mar 2024 03:24

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Contributors

Author: Arunabhiram Chutia
Author: Ian P. Silverwood
Author: Matthew R. Farrow
Author: David O. Scanlon
Author: Peter Wells ORCID iD
Author: Michael Bowker
Author: Stewart F. Parker
Author: C. Richard A. Catlow

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