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Deactivation of a single-site gold-on-carbon acetylene hydrochlorination catalyst: An X-ray absorption and inelastic neutron scattering study

Deactivation of a single-site gold-on-carbon acetylene hydrochlorination catalyst: An X-ray absorption and inelastic neutron scattering study
Deactivation of a single-site gold-on-carbon acetylene hydrochlorination catalyst: An X-ray absorption and inelastic neutron scattering study
Single-site Au species supported on carbon have been shown to be the active sites for acetylene hydrochlorination. The evolution of these single-site species has been monitored by Au L3 Xray Absorption Spectroscopy (XAS). Alternating between a standard reaction mixture of HCl/C2H2 and the single reactants, has provided insights into the reaction mechanism and catalyst deactivation processes. We demonstrate that oxidative addition of HCl across an Au(I) chloride species requires concerted addition with C2H2, in accordance with both the XAS measurements of Au oxidation state and the reaction kinetics being 1st order with respect to each reactant. The addition of excess C2H2 changes the Au speciation and results in the formation of oligomeric acetylene species which were detected by inelastic neutron scattering. Catalyst deactivation at extended reaction times can be correlated with the formation of metallic Au particles. The presence of this Au(0) species generated during the sequential gas experiments or after prolonged reaction times, results in the analysis of thenormalized near edge white line intensity of the Au L3 X-ray absorption spectrum alone becoming an unsuitable guide for identifying the active Au species, affecting the strong correlation between normalized white line height and VCM productivity usually observed in the active catalyst. Thus, a combination of scanning transmission electron microscopy and detailed modelling of whole XAS spectrum was required to distinguish active Au(I) and Au(III) species from the spectator Au(0) component.
2155-5435
1-40
Malta, Grazia
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Freakley, Simon J.
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Kondrat, Simon
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Davies, Catherine
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Dawson, Simon
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Liu, Xi
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Lu, Li
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Dymkowski, Krzysztof
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Fernandez-Alonso, F
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Mukhopadhyay, Sanghamitra
bb9515a6-21d0-498b-b8f0-1dc75eb6501c
Gibson, Emma
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Wells, Peter P.
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Parker, Stewart
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Kiely, C.J.
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Hutchings, Graham
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Malta, Grazia
f8644878-b7a5-4e78-b099-8ea07b1dd233
Freakley, Simon J.
4d006e28-df91-4fdf-b820-a6377ee38741
Kondrat, Simon
19896985-2ae2-437e-82ec-e5457d692b1a
Davies, Catherine
949b8010-31a3-476b-bc0a-8b1f3c6aecd1
Dawson, Simon
19adb711-7180-489a-8501-d460f5001920
Liu, Xi
9589a507-97cc-4672-845c-134499274338
Lu, Li
63ce5393-0cd7-448d-b40b-9ad6ecda7603
Dymkowski, Krzysztof
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Fernandez-Alonso, F
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Mukhopadhyay, Sanghamitra
bb9515a6-21d0-498b-b8f0-1dc75eb6501c
Gibson, Emma
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Wells, Peter P.
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Parker, Stewart
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Kiely, C.J.
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Hutchings, Graham
9d47193f-dea0-410b-8dad-8a7a4d807ce6

Malta, Grazia, Freakley, Simon J., Kondrat, Simon, Davies, Catherine, Dawson, Simon, Liu, Xi, Lu, Li, Dymkowski, Krzysztof, Fernandez-Alonso, F, Mukhopadhyay, Sanghamitra, Gibson, Emma, Wells, Peter P., Parker, Stewart, Kiely, C.J. and Hutchings, Graham (2018) Deactivation of a single-site gold-on-carbon acetylene hydrochlorination catalyst: An X-ray absorption and inelastic neutron scattering study. ACS Catalysis, 1-40. (doi:10.1021/acscatal.8b02232).

Record type: Article

Abstract

Single-site Au species supported on carbon have been shown to be the active sites for acetylene hydrochlorination. The evolution of these single-site species has been monitored by Au L3 Xray Absorption Spectroscopy (XAS). Alternating between a standard reaction mixture of HCl/C2H2 and the single reactants, has provided insights into the reaction mechanism and catalyst deactivation processes. We demonstrate that oxidative addition of HCl across an Au(I) chloride species requires concerted addition with C2H2, in accordance with both the XAS measurements of Au oxidation state and the reaction kinetics being 1st order with respect to each reactant. The addition of excess C2H2 changes the Au speciation and results in the formation of oligomeric acetylene species which were detected by inelastic neutron scattering. Catalyst deactivation at extended reaction times can be correlated with the formation of metallic Au particles. The presence of this Au(0) species generated during the sequential gas experiments or after prolonged reaction times, results in the analysis of thenormalized near edge white line intensity of the Au L3 X-ray absorption spectrum alone becoming an unsuitable guide for identifying the active Au species, affecting the strong correlation between normalized white line height and VCM productivity usually observed in the active catalyst. Thus, a combination of scanning transmission electron microscopy and detailed modelling of whole XAS spectrum was required to distinguish active Au(I) and Au(III) species from the spectator Au(0) component.

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acscatal.8b02232 - Accepted Manuscript
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Accepted/In Press date: 27 July 2018
e-pub ahead of print date: 27 July 2018
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Identifiers

Local EPrints ID: 422723
URI: http://eprints.soton.ac.uk/id/eprint/422723
DOI: doi:10.1021/acscatal.8b02232
ISSN: 2155-5435
PURE UUID: e31cf9d1-0667-4a26-86f4-51f0b4023732
ORCID for Peter P. Wells: ORCID iD orcid.org/0000-0002-0859-9172

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Date deposited: 01 Aug 2018 16:30
Last modified: 16 Mar 2024 06:57

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Contributors

Author: Grazia Malta
Author: Simon J. Freakley
Author: Simon Kondrat
Author: Catherine Davies
Author: Simon Dawson
Author: Xi Liu
Author: Li Lu
Author: Krzysztof Dymkowski
Author: F Fernandez-Alonso
Author: Sanghamitra Mukhopadhyay
Author: Emma Gibson
Author: Peter P. Wells ORCID iD
Author: Stewart Parker
Author: C.J. Kiely
Author: Graham Hutchings

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