Spatial Profiling of a Pd/Al2O3 Catalyst during Selective Ammonia Oxidation
Spatial Profiling of a Pd/Al2O3 Catalyst during Selective Ammonia Oxidation
The utilization of operando spectroscopy has allowed us to watch the dynamic nature of supported metal nanoparticles. However, the realization that subtle changes to environmental conditions affect the form of the catalyst necessitates that we assess the structure of the catalyst across the reactant/product gradient that exists across a fixed bed reactor. In this study, we have performed spatial profiling of a Pd/Al2O3 catalyst during NH3 oxidation, simultaneously collecting mass spectrometry and X-ray absorption spectroscopy data at discrete axial positions along the length of the catalyst bed. The spatial analysis has provided unique insights into the structure–activity relationships that govern selective NH3 oxidation—(i) our data is consistent with the presence of PdNx after the spectroscopic signatures for bulk PdNx disappear and that there is a direct correlation to the presence of this structure and the selectivity toward N2; (ii) at high temperatures, ≥400 °C, we propose that there are two simultaneous reaction pathways—the oxidation of NH3 to NOx by PdO and the subsequent catalytic reduction of NOx by NH3 to produce N2. The results in this study confirm the structural and catalytic diversity that exists during catalysis and the need for such an understanding if improvements to important emission control technologies, such as the selective catalytic oxidation of NH3, are to be made.
ammonia oxidation, operando spectroscopy, Pd nanoparticles, SPACI-FB, eterogeneous catalysis
2141–2149
Decarolis, Donato
03364b3b-270b-4666-abee-36a8d455eadc
Clark, Adam H.
be768792-2596-41a8-bed4-dfe8a49ca115
Pellegrinelli, Tommaso
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Nachtegaal, Maarten
37fbcbc5-08e8-4eda-9350-2b162693013f
Lynch, Evan William
6eecfe8a-33be-44bb-9498-e1d378d526ff
Catlow, C. Richard A.
50b88125-9415-4b37-9146-af6783e42510
Gibson, Emma K.
738c74e4-ab68-42fe-bda8-9d4a43669b31
Goguet, Alexandre
4de6e217-9733-4d26-b041-ab996672d919
Wells, Peter P.
bc4fdc2d-a490-41bf-86cc-400edecf2266
Decarolis, Donato
03364b3b-270b-4666-abee-36a8d455eadc
Clark, Adam H.
be768792-2596-41a8-bed4-dfe8a49ca115
Pellegrinelli, Tommaso
7b78d60c-1c3b-4892-8e3e-e48f375ea17a
Nachtegaal, Maarten
37fbcbc5-08e8-4eda-9350-2b162693013f
Lynch, Evan William
6eecfe8a-33be-44bb-9498-e1d378d526ff
Catlow, C. Richard A.
50b88125-9415-4b37-9146-af6783e42510
Gibson, Emma K.
738c74e4-ab68-42fe-bda8-9d4a43669b31
Goguet, Alexandre
4de6e217-9733-4d26-b041-ab996672d919
Wells, Peter P.
bc4fdc2d-a490-41bf-86cc-400edecf2266
Decarolis, Donato, Clark, Adam H., Pellegrinelli, Tommaso, Nachtegaal, Maarten, Lynch, Evan William, Catlow, C. Richard A., Gibson, Emma K., Goguet, Alexandre and Wells, Peter P.
(2021)
Spatial Profiling of a Pd/Al2O3 Catalyst during Selective Ammonia Oxidation.
ACS Catalysis, 11 (4), .
(doi:10.1021/acscatal.0c05356).
Abstract
The utilization of operando spectroscopy has allowed us to watch the dynamic nature of supported metal nanoparticles. However, the realization that subtle changes to environmental conditions affect the form of the catalyst necessitates that we assess the structure of the catalyst across the reactant/product gradient that exists across a fixed bed reactor. In this study, we have performed spatial profiling of a Pd/Al2O3 catalyst during NH3 oxidation, simultaneously collecting mass spectrometry and X-ray absorption spectroscopy data at discrete axial positions along the length of the catalyst bed. The spatial analysis has provided unique insights into the structure–activity relationships that govern selective NH3 oxidation—(i) our data is consistent with the presence of PdNx after the spectroscopic signatures for bulk PdNx disappear and that there is a direct correlation to the presence of this structure and the selectivity toward N2; (ii) at high temperatures, ≥400 °C, we propose that there are two simultaneous reaction pathways—the oxidation of NH3 to NOx by PdO and the subsequent catalytic reduction of NOx by NH3 to produce N2. The results in this study confirm the structural and catalytic diversity that exists during catalysis and the need for such an understanding if improvements to important emission control technologies, such as the selective catalytic oxidation of NH3, are to be made.
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e-pub ahead of print date: 3 February 2021
Keywords:
ammonia oxidation, operando spectroscopy, Pd nanoparticles, SPACI-FB, eterogeneous catalysis
Identifiers
Local EPrints ID: 501426
URI: http://eprints.soton.ac.uk/id/eprint/501426
ISSN: 2155-5435
PURE UUID: 337b78ea-9b0c-4f72-9ff2-cd9f4194e1f1
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Date deposited: 30 May 2025 16:57
Last modified: 31 May 2025 01:41
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Contributors
Author:
Donato Decarolis
Author:
Adam H. Clark
Author:
Tommaso Pellegrinelli
Author:
Maarten Nachtegaal
Author:
Evan William Lynch
Author:
C. Richard A. Catlow
Author:
Emma K. Gibson
Author:
Alexandre Goguet
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