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Bridging the size gap between experiment and theory: large-scale DFT calculations on realistic sized Pd particles for acetylene hydrogenation

Bridging the size gap between experiment and theory: large-scale DFT calculations on realistic sized Pd particles for acetylene hydrogenation
Bridging the size gap between experiment and theory: large-scale DFT calculations on realistic sized Pd particles for acetylene hydrogenation
Metal nanoparticles, often supported on metal oxide promoters, are a cornerstone of heterogeneous catalysis. Experimentally, size effects are well-established and are manifested through changes to catalyst selectivity, activity and durability. Density Functional Theory (DFT) calculations have provided an attractive way to study these effects and rationalise the change in nanoparticle properties. However such computational studies are typically limited to smaller nanoparticles (approximately up to 50 atoms) due to the large computational cost of DFT. How well can such simulations describe the electronic properties of the much larger nanoparticles that are often used in practice? In this study, we use the ONETEP code, which is able to achieve more favourable computational scaling for metallic nanoparticles, to bridge this size gap. We present DFT calculations on entire Pd and Pd carbide nanoparticles of more than 300 atoms (approximately 2.5 nm diameter), and find major differences in the electronic structure of such large nanoparticles, in comparison to the commonly investigated smaller clusters. These differences are also manifested in the calculated chemical properties such as adsorption energies for C2H2, C2H4 and C2H6 on the pristine Pd and PdCx nanoparticles which are significantly larger (up to twice in value) for the ∼300 atoms structures. Furthermore, the adsorption of C2H2 and C2H4 on PdCx nanoparticles becomes weaker as more C is introduced in the Pd lattice whilst the impact of C concentration is also observed in the calculated reaction energies towards the hydrogenation of C2H2, where the formation of C2H6 is hindered. Our simulations show that PdCx nanoparticles of about 5% C per atom fraction and diameter of 2.5 nm could be potential candidate catalysts of high activity in hydrogenation reactions. The paradigm presented in this study will enable DFT to be applied on similar sized metal catalyst nanoparticles as in experimental investigations, strengthening the synergy between simulation and experiment in catalysis.
2046-2069
27799-27808
Kordatos, Apostolos
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Mohammed, Khaled
1c3c5641-4d0a-4c4d-bb26-fe733b8dbf63
Vakili, Reza
7e37d2f5-ccc7-4530-9b77-898141c35ab2
Manyar, Haresh
aad00507-84ce-431c-ac0b-85dc1992ad6b
Goguet, Alexandre
4de6e217-9733-4d26-b041-ab996672d919
Gibson, Emma K.
738c74e4-ab68-42fe-bda8-9d4a43669b31
Carravetta, Marina
1b12fa96-4a6a-4689-ab3b-ccc68f1d7691
Wells, Peter
bc4fdc2d-a490-41bf-86cc-400edecf2266
Skylaris, Chris-Kriton
8f593d13-3ace-4558-ba08-04e48211af61
Kordatos, Apostolos
f95fcb92-92b1-4ec8-991a-de7609845493
Mohammed, Khaled
1c3c5641-4d0a-4c4d-bb26-fe733b8dbf63
Vakili, Reza
7e37d2f5-ccc7-4530-9b77-898141c35ab2
Manyar, Haresh
aad00507-84ce-431c-ac0b-85dc1992ad6b
Goguet, Alexandre
4de6e217-9733-4d26-b041-ab996672d919
Gibson, Emma K.
738c74e4-ab68-42fe-bda8-9d4a43669b31
Carravetta, Marina
1b12fa96-4a6a-4689-ab3b-ccc68f1d7691
Wells, Peter
bc4fdc2d-a490-41bf-86cc-400edecf2266
Skylaris, Chris-Kriton
8f593d13-3ace-4558-ba08-04e48211af61

Kordatos, Apostolos, Mohammed, Khaled, Vakili, Reza, Manyar, Haresh, Goguet, Alexandre, Gibson, Emma K., Carravetta, Marina, Wells, Peter and Skylaris, Chris-Kriton (2024) Bridging the size gap between experiment and theory: large-scale DFT calculations on realistic sized Pd particles for acetylene hydrogenation. RSC Advances, 14 (38), 27799-27808. (doi:10.1039/D4RA03369H).

Record type: Article

Abstract

Metal nanoparticles, often supported on metal oxide promoters, are a cornerstone of heterogeneous catalysis. Experimentally, size effects are well-established and are manifested through changes to catalyst selectivity, activity and durability. Density Functional Theory (DFT) calculations have provided an attractive way to study these effects and rationalise the change in nanoparticle properties. However such computational studies are typically limited to smaller nanoparticles (approximately up to 50 atoms) due to the large computational cost of DFT. How well can such simulations describe the electronic properties of the much larger nanoparticles that are often used in practice? In this study, we use the ONETEP code, which is able to achieve more favourable computational scaling for metallic nanoparticles, to bridge this size gap. We present DFT calculations on entire Pd and Pd carbide nanoparticles of more than 300 atoms (approximately 2.5 nm diameter), and find major differences in the electronic structure of such large nanoparticles, in comparison to the commonly investigated smaller clusters. These differences are also manifested in the calculated chemical properties such as adsorption energies for C2H2, C2H4 and C2H6 on the pristine Pd and PdCx nanoparticles which are significantly larger (up to twice in value) for the ∼300 atoms structures. Furthermore, the adsorption of C2H2 and C2H4 on PdCx nanoparticles becomes weaker as more C is introduced in the Pd lattice whilst the impact of C concentration is also observed in the calculated reaction energies towards the hydrogenation of C2H2, where the formation of C2H6 is hindered. Our simulations show that PdCx nanoparticles of about 5% C per atom fraction and diameter of 2.5 nm could be potential candidate catalysts of high activity in hydrogenation reactions. The paradigm presented in this study will enable DFT to be applied on similar sized metal catalyst nanoparticles as in experimental investigations, strengthening the synergy between simulation and experiment in catalysis.

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Accepted/In Press date: 18 August 2024
Published date: 2 September 2024
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Identifiers

Local EPrints ID: 493792
URI: http://eprints.soton.ac.uk/id/eprint/493792
DOI: doi:10.1039/D4RA03369H
ISSN: 2046-2069
PURE UUID: 6426a2c1-c249-44dd-9cc2-07c7ca07d21d
ORCID for Apostolos Kordatos: ORCID iD orcid.org/0000-0002-0183-8142
ORCID for Khaled Mohammed: ORCID iD orcid.org/0000-0002-9538-0936
ORCID for Marina Carravetta: ORCID iD orcid.org/0000-0002-6296-2104
ORCID for Peter Wells: ORCID iD orcid.org/0000-0002-0859-9172
ORCID for Chris-Kriton Skylaris: ORCID iD orcid.org/0000-0003-0258-3433

Catalogue record

Date deposited: 12 Sep 2024 16:57
Last modified: 21 Nov 2024 02:58

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Contributors

Author: Apostolos Kordatos ORCID iD
Author: Khaled Mohammed ORCID iD
Author: Reza Vakili
Author: Haresh Manyar
Author: Alexandre Goguet
Author: Emma K. Gibson
Author: Marina Carravetta ORCID iD
Author: Peter Wells ORCID iD
Author: Chris-Kriton Skylaris ORCID iD

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