Chemical imaging of the sulfur-induced deactivation of Cu/ZnO catalyst bodies

Andrew M Beale; Emma K Gibson; Matthew G O'Brien; Simon D M Jacques; Robert J Cernik; Marco Di Michiel; Paul D Cobden; Oezlem Pirgon-Galin; Leon van de Water; Michael J Watson; Bert M Weckhuysen; ? ? Pirgon-Galin; LVD Water

doi:10.1016/j.jcat.2014.04.007

Chemical imaging of the sulfur-induced deactivation of Cu/ZnO catalyst bodies

Andrew M Beale, Emma K Gibson, Matthew G O'Brien, Simon D M Jacques, Robert J Cernik, Marco Di Michiel, Paul D Cobden, Oezlem Pirgon-Galin, Leon van de Water, Michael J Watson, Bert M Weckhuysen, ? ? Pirgon-Galin, LVD Water

Research output: Contribution to journal › Article › peer-review

Abstract

The effects of sulfur poisoning on the water-gas shift (WGS) activity of industrial Cu/ZnO/Al2O3 catalyst bodies have been studied. The samples were characterized using chem. imaging methods, including XRD-CT, XAFS mapping, and XRF, in order to understand the process by which accelerated sulfur poisoning leads to catalyst deactivation. After ∼90 h on stream, all catalysts exhibited reduced activity; the higher the H2S concn., the greater the extent of deactivation. Non-invasive XRD-CT measurements performed on intact samples recovered from the reactor revealed the formation of sulfide phases, including sphalerite (β-ZnS) and cryst. CuS, Cu2S, and CuSO4 phases. These sulfide phases were distributed predominantly as a graduated corona around the sample edge reaching ∼1.5 mm thick for expts. performed in the highest concn. of 500 ppm H2S. XAFS mapping, which is particularly sensitive to the local coordination environment around the element being probed, confirmed the presence of mixed Cu/Zn-O/S coordination environments and that the core of the sample remained sulfur-free. A combination of XRD-CT and XRF revealed that CuS appeared to be mobile under reaction conditions resulting in the redistribution of Cu toward the very edge of the samples. A combination of techniques has therefore demonstrated that H2S deactivation of Cu/ZnO/Al2O3 catalyst bodies occurs via phase transformation of the active Cu/ZnO phase into sulfides and redistribution of these components over the sample instead of Cu active site poisoning by Sads species. [on SciFinder(R)]

Original language	English
Pages (from-to)	94-100
Number of pages	7
Journal	Journal of Catalysis
Volume	314
DOIs	https://doi.org/10.1016/j.jcat.2014.04.007
Publication status	Published - 2014

Keywords

Adsorbed substances
Catalyst poisoning
Catalyst supports
Catalysts
EXAFS spectra
Imaging
Phase composition
Surface reaction
Surface structure
Tomography
Water gas shift reaction catalysts
Water vapor
X-ray diffraction
X-ray fluorescence
XAFS spectra (chem. imaging of sulfur-induced deactivation of Cu/ZnO catalyst bodies)
imaging sulfur induced deactivation copper zinc oxide catalyst

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10.1016/j.jcat.2014.04.007

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Beale, A. M., Gibson, E. K., O'Brien, M. G., Jacques, S. D. M., Cernik, R. J., Di Michiel, M., Cobden, P. D., Pirgon-Galin, O., van de Water, L., Watson, M. J., Weckhuysen, B. M., Pirgon-Galin, . ., & Water, LVD. (2014). Chemical imaging of the sulfur-induced deactivation of Cu/ZnO catalyst bodies. Journal of Catalysis , 314, 94-100. https://doi.org/10.1016/j.jcat.2014.04.007

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title = "Chemical imaging of the sulfur-induced deactivation of Cu/ZnO catalyst bodies",

abstract = "The effects of sulfur poisoning on the water-gas shift (WGS) activity of industrial Cu/ZnO/Al2O3 catalyst bodies have been studied. The samples were characterized using chem. imaging methods, including XRD-CT, XAFS mapping, and XRF, in order to understand the process by which accelerated sulfur poisoning leads to catalyst deactivation. After ∼90 h on stream, all catalysts exhibited reduced activity; the higher the H2S concn., the greater the extent of deactivation. Non-invasive XRD-CT measurements performed on intact samples recovered from the reactor revealed the formation of sulfide phases, including sphalerite (β-ZnS) and cryst. CuS, Cu2S, and CuSO4 phases. These sulfide phases were distributed predominantly as a graduated corona around the sample edge reaching ∼1.5 mm thick for expts. performed in the highest concn. of 500 ppm H2S. XAFS mapping, which is particularly sensitive to the local coordination environment around the element being probed, confirmed the presence of mixed Cu/Zn-O/S coordination environments and that the core of the sample remained sulfur-free. A combination of XRD-CT and XRF revealed that CuS appeared to be mobile under reaction conditions resulting in the redistribution of Cu toward the very edge of the samples. A combination of techniques has therefore demonstrated that H2S deactivation of Cu/ZnO/Al2O3 catalyst bodies occurs via phase transformation of the active Cu/ZnO phase into sulfides and redistribution of these components over the sample instead of Cu active site poisoning by Sads species. [on SciFinder(R)]",

keywords = "Adsorbed substances, Catalyst poisoning, Catalyst supports, Catalysts, EXAFS spectra, Imaging, Phase composition, Surface reaction, Surface structure, Tomography, Water gas shift reaction catalysts, Water vapor, X-ray diffraction, X-ray fluorescence, XAFS spectra (chem. imaging of sulfur-induced deactivation of Cu/ZnO catalyst bodies), imaging sulfur induced deactivation copper zinc oxide catalyst",

author = "Beale, {Andrew M} and Gibson, {Emma K} and O'Brien, {Matthew G} and Jacques, {Simon D M} and Cernik, {Robert J} and {Di Michiel}, Marco and Cobden, {Paul D} and Oezlem Pirgon-Galin and {van de Water}, Leon and Watson, {Michael J} and Weckhuysen, {Bert M} and Pirgon-Galin, {? ?} and LVD Water",

note = "CAN 160:744865 Catalysis, Reaction Kinetics, and Inorganic Reaction Mechanisms 1317-40-4 (Copper sulfide (CuS)); 7758-98-7 (Copper sulfate); 22205-45-4 (Copper sulfide (Cu2S)) Role: CAT (Catalyst use), FMU (Formation, unclassified), PEP (Physical, engineering or chemical process), PRP (Properties), FORM (Formation, nonpreparative), PROC (Process), USES (Uses) (chem. imaging of sulfur-induced deactivation of Cu/ZnO catalyst bodies); 1314-13-2 (Zinc oxide); 7440-50-8 (Copper) Role: CAT (Catalyst use), PEP (Physical, engineering or chemical process), PRP (Properties), RCT (Reactant), PROC (Process), USES (Uses), RACT (Reactant or reagent) (chem. imaging of sulfur-induced deactivation of Cu/ZnO catalyst bodies); 124-38-9 (Carbon dioxide); 1333-74-0 (Hydrogen) Role: FMU (Formation, unclassified), PEP (Physical, engineering or chemical process), PRP (Properties), FORM (Formation, nonpreparative), PROC (Process) (chem. imaging of sulfur-induced deactivation of Cu/ZnO catalyst bodies); 7704-34-9 (Sulfur); 7783-06-4 (Hydrogen sulfide) Role: PEP (Physical, engineering or chemical process), PROC (Process) (chem. imaging of sulfur-induced deactivation of Cu/ZnO catalyst bodies); 630-08-0 (Carbon monoxide); 7732-18-5 (Water) Role: PEP (Physical, engineering or chemical process), PRP (Properties), RCT (Reactant), PROC (Process), RACT (Reactant or reagent) (chem. imaging of sulfur-induced deactivation of Cu/ZnO catalyst bodies); 1314-98-3 (Zinc sulfide) Role: CAT (Catalyst use), FMU (Formation, unclassified), PEP (Physical, engineering or chemical process), PRP (Properties), FORM (Formation, nonpreparative), PROC (Process), USES (Uses) (β-; chem. imaging of sulfur-induced deactivation of Cu/ZnO catalyst bodies)",

year = "2014",

doi = "10.1016/j.jcat.2014.04.007",

language = "English",

volume = "314",

pages = "94--100",

journal = "Journal of Catalysis ",

issn = "0021-9517",

publisher = "Elsevier BV",

}

TY - JOUR

T1 - Chemical imaging of the sulfur-induced deactivation of Cu/ZnO catalyst bodies

AU - Beale, Andrew M

AU - Gibson, Emma K

AU - O'Brien, Matthew G

AU - Jacques, Simon D M

AU - Cernik, Robert J

AU - Di Michiel, Marco

AU - Cobden, Paul D

AU - Pirgon-Galin, Oezlem

AU - van de Water, Leon

AU - Watson, Michael J

AU - Weckhuysen, Bert M

AU - Pirgon-Galin, ? ?

AU - Water, LVD

N1 - CAN 160:744865 Catalysis, Reaction Kinetics, and Inorganic Reaction Mechanisms 1317-40-4 (Copper sulfide (CuS)); 7758-98-7 (Copper sulfate); 22205-45-4 (Copper sulfide (Cu2S)) Role: CAT (Catalyst use), FMU (Formation, unclassified), PEP (Physical, engineering or chemical process), PRP (Properties), FORM (Formation, nonpreparative), PROC (Process), USES (Uses) (chem. imaging of sulfur-induced deactivation of Cu/ZnO catalyst bodies); 1314-13-2 (Zinc oxide); 7440-50-8 (Copper) Role: CAT (Catalyst use), PEP (Physical, engineering or chemical process), PRP (Properties), RCT (Reactant), PROC (Process), USES (Uses), RACT (Reactant or reagent) (chem. imaging of sulfur-induced deactivation of Cu/ZnO catalyst bodies); 124-38-9 (Carbon dioxide); 1333-74-0 (Hydrogen) Role: FMU (Formation, unclassified), PEP (Physical, engineering or chemical process), PRP (Properties), FORM (Formation, nonpreparative), PROC (Process) (chem. imaging of sulfur-induced deactivation of Cu/ZnO catalyst bodies); 7704-34-9 (Sulfur); 7783-06-4 (Hydrogen sulfide) Role: PEP (Physical, engineering or chemical process), PROC (Process) (chem. imaging of sulfur-induced deactivation of Cu/ZnO catalyst bodies); 630-08-0 (Carbon monoxide); 7732-18-5 (Water) Role: PEP (Physical, engineering or chemical process), PRP (Properties), RCT (Reactant), PROC (Process), RACT (Reactant or reagent) (chem. imaging of sulfur-induced deactivation of Cu/ZnO catalyst bodies); 1314-98-3 (Zinc sulfide) Role: CAT (Catalyst use), FMU (Formation, unclassified), PEP (Physical, engineering or chemical process), PRP (Properties), FORM (Formation, nonpreparative), PROC (Process), USES (Uses) (β-; chem. imaging of sulfur-induced deactivation of Cu/ZnO catalyst bodies)

PY - 2014

Y1 - 2014

N2 - The effects of sulfur poisoning on the water-gas shift (WGS) activity of industrial Cu/ZnO/Al2O3 catalyst bodies have been studied. The samples were characterized using chem. imaging methods, including XRD-CT, XAFS mapping, and XRF, in order to understand the process by which accelerated sulfur poisoning leads to catalyst deactivation. After ∼90 h on stream, all catalysts exhibited reduced activity; the higher the H2S concn., the greater the extent of deactivation. Non-invasive XRD-CT measurements performed on intact samples recovered from the reactor revealed the formation of sulfide phases, including sphalerite (β-ZnS) and cryst. CuS, Cu2S, and CuSO4 phases. These sulfide phases were distributed predominantly as a graduated corona around the sample edge reaching ∼1.5 mm thick for expts. performed in the highest concn. of 500 ppm H2S. XAFS mapping, which is particularly sensitive to the local coordination environment around the element being probed, confirmed the presence of mixed Cu/Zn-O/S coordination environments and that the core of the sample remained sulfur-free. A combination of XRD-CT and XRF revealed that CuS appeared to be mobile under reaction conditions resulting in the redistribution of Cu toward the very edge of the samples. A combination of techniques has therefore demonstrated that H2S deactivation of Cu/ZnO/Al2O3 catalyst bodies occurs via phase transformation of the active Cu/ZnO phase into sulfides and redistribution of these components over the sample instead of Cu active site poisoning by Sads species. [on SciFinder(R)]

AB - The effects of sulfur poisoning on the water-gas shift (WGS) activity of industrial Cu/ZnO/Al2O3 catalyst bodies have been studied. The samples were characterized using chem. imaging methods, including XRD-CT, XAFS mapping, and XRF, in order to understand the process by which accelerated sulfur poisoning leads to catalyst deactivation. After ∼90 h on stream, all catalysts exhibited reduced activity; the higher the H2S concn., the greater the extent of deactivation. Non-invasive XRD-CT measurements performed on intact samples recovered from the reactor revealed the formation of sulfide phases, including sphalerite (β-ZnS) and cryst. CuS, Cu2S, and CuSO4 phases. These sulfide phases were distributed predominantly as a graduated corona around the sample edge reaching ∼1.5 mm thick for expts. performed in the highest concn. of 500 ppm H2S. XAFS mapping, which is particularly sensitive to the local coordination environment around the element being probed, confirmed the presence of mixed Cu/Zn-O/S coordination environments and that the core of the sample remained sulfur-free. A combination of XRD-CT and XRF revealed that CuS appeared to be mobile under reaction conditions resulting in the redistribution of Cu toward the very edge of the samples. A combination of techniques has therefore demonstrated that H2S deactivation of Cu/ZnO/Al2O3 catalyst bodies occurs via phase transformation of the active Cu/ZnO phase into sulfides and redistribution of these components over the sample instead of Cu active site poisoning by Sads species. [on SciFinder(R)]

KW - Adsorbed substances

KW - Catalyst poisoning

KW - Catalyst supports

KW - Catalysts

KW - EXAFS spectra

KW - Imaging

KW - Phase composition

KW - Surface reaction

KW - Surface structure

KW - Tomography

KW - Water gas shift reaction catalysts

KW - Water vapor

KW - X-ray diffraction

KW - X-ray fluorescence

KW - XAFS spectra (chem. imaging of sulfur-induced deactivation of Cu/ZnO catalyst bodies)

KW - imaging sulfur induced deactivation copper zinc oxide catalyst

U2 - 10.1016/j.jcat.2014.04.007

DO - 10.1016/j.jcat.2014.04.007

M3 - Article

SN - 0021-9517

VL - 314

SP - 94

EP - 100

JO - Journal of Catalysis

JF - Journal of Catalysis

ER -

Chemical imaging of the sulfur-induced deactivation of Cu/ZnO catalyst bodies

Abstract

Keywords

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