A comparative study on the stability of the furfural molecule on the low index Ni, Pd and Pt surfaces
A comparative study on the stability of the furfural molecule on the low index Ni, Pd and Pt surfaces
We present a comparative density functional theory investigation of the furfural (Ff ) molecule on the low index Ni, Pd and Pt surfaces to understand its geometrical and electronic properties to gain mechanistic insights into the experimentally measured catalytic reactivities of these metal catalysts. We show that the number of metal d-states, which hybridize with the nearest C and O p-orbitals of the Ff molecule, can be used to explain the stability of the Ff molecule on these surfaces. We find that the hybridization between atoms with higher electronegativity and the metal d-states plays a crucial role in determining the stability of these systems. Furthermore, we also find electron transfer from metal to the Ff molecule on the Ni and Pd surfaces, with a reverse process occurring on the Pt surface.,The Coordinate folder contains all the relaxed structures of the furfural molecule on the low index Ni, Pd and Pt surfaces. There are 9 folders, which includesaNi111bNi110cNi100dPd111ePd110fPd100gPt111hPt110iPt100For any further details please contact Dr. Arunabhiram Chutia (achutia@lincoln.ac.uk),The data contains the optimised geometries of all the models used in this study.
Khan, Alveena Z.
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Alitt, Jacob
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Germaney, Rhiannon
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Hamada, Ikutaro
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Wells, Peter P.
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Dimitratos, Nikolaos
a4385576-4a05-478b-8389-460bfb43412b
Catlow, C. Richard A.
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Villa, Alberto
d1f6646b-f0d4-420c-8a52-c09663f46e5f
Chutia, Arunabhiram
fe207bfe-0a7e-4369-8e62-bfa575399f83
Khan, Alveena Z.
6b68a932-2480-4084-844d-c6a3b75c77c8
Alitt, Jacob
4a0f8747-d15f-41d7-9e30-676282b81429
Germaney, Rhiannon
11a011c5-e247-4c3e-9964-ee89d9c51ca6
Hamada, Ikutaro
9f1cb3f1-ed7c-419f-8d55-c17f38a04ae9
Wells, Peter P.
bc4fdc2d-a490-41bf-86cc-400edecf2266
Dimitratos, Nikolaos
a4385576-4a05-478b-8389-460bfb43412b
Catlow, C. Richard A.
50b88125-9415-4b37-9146-af6783e42510
Villa, Alberto
d1f6646b-f0d4-420c-8a52-c09663f46e5f
Chutia, Arunabhiram
fe207bfe-0a7e-4369-8e62-bfa575399f83
(2021)
A comparative study on the stability of the furfural molecule on the low index Ni, Pd and Pt surfaces.
DRYAD
doi:10.5061/dryad.0zpc866zm
[Dataset]
Abstract
We present a comparative density functional theory investigation of the furfural (Ff ) molecule on the low index Ni, Pd and Pt surfaces to understand its geometrical and electronic properties to gain mechanistic insights into the experimentally measured catalytic reactivities of these metal catalysts. We show that the number of metal d-states, which hybridize with the nearest C and O p-orbitals of the Ff molecule, can be used to explain the stability of the Ff molecule on these surfaces. We find that the hybridization between atoms with higher electronegativity and the metal d-states plays a crucial role in determining the stability of these systems. Furthermore, we also find electron transfer from metal to the Ff molecule on the Ni and Pd surfaces, with a reverse process occurring on the Pt surface.,The Coordinate folder contains all the relaxed structures of the furfural molecule on the low index Ni, Pd and Pt surfaces. There are 9 folders, which includesaNi111bNi110cNi100dPd111ePd110fPd100gPt111hPt110iPt100For any further details please contact Dr. Arunabhiram Chutia (achutia@lincoln.ac.uk),The data contains the optimised geometries of all the models used in this study.
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Published date: 1 January 2021
Identifiers
Local EPrints ID: 457345
URI: http://eprints.soton.ac.uk/id/eprint/457345
PURE UUID: 1136a7fb-b966-4e72-9f58-53fe7ca418f7
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Date deposited: 01 Jun 2022 16:45
Last modified: 02 Aug 2023 01:48
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Contributors
Contributor:
Alveena Z. Khan
Contributor:
Jacob Alitt
Contributor:
Rhiannon Germaney
Contributor:
Ikutaro Hamada
Contributor:
Nikolaos Dimitratos
Contributor:
C. Richard A. Catlow
Contributor:
Alberto Villa
Contributor:
Arunabhiram Chutia
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