In situ structural evolution of single particle model catalysts under ambient pressure reaction conditions

Sara Fernández; Lu Gao; Jan Philipp Hofmann; Jérôme Carnis; Stéphane Labat; Gilbert A. Chahine; Arno J.F. Van Hoof; M. W.G.M. Verhoeven; Tobias U. Schülli; Emiel J.M. Hensen; Olivier Thomas; Marie Ingrid Richard

doi:10.1039/C8NR08414A

In situ structural evolution of single particle model catalysts under ambient pressure reaction conditions

Sara Fernández, Lu Gao, Jan Philipp Hofmann, Jérôme Carnis, Stéphane Labat, Gilbert A. Chahine, Arno J.F. Van Hoof, M. W.G.M. Verhoeven, Tobias U. Schülli, Emiel J.M. Hensen, Olivier Thomas, Marie Ingrid Richard (Corresponding author)

Inorganic Materials & Catalysis

Onderzoeksoutput: Bijdrage aan tijdschrift › Tijdschriftartikel › Academic › peer review

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The catalytic activity of metal nanoparticles can be altered by applying strain, which changes the crystalline lattice spacing and modifies the electronic properties of the metal. Understanding the role of elastic strain during catalytic reactions is thus crucial for catalyst design. Here, we show how single highly faceted Pt nanoparticles expand or contract upon interaction with different gas atmospheres using in situ nano-focused coherent X-ray diffraction imaging. We also demonstrate inter-particle heterogeneities, as they differ in development of strain under CO oxidation reaction conditions. The reported observations offer new insights into the design of catalysts exploiting strain effects.

Originele taal-2	Engels
Pagina's (van-tot)	331-338
Aantal pagina's	8
Tijdschrift	Nanoscale
Volume	11
Nummer van het tijdschrift	1
DOI's	https://doi.org/10.1039/C8NR08414A
Status	Gepubliceerd - 7 jan. 2019

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title = "In situ structural evolution of single particle model catalysts under ambient pressure reaction conditions",

abstract = "The catalytic activity of metal nanoparticles can be altered by applying strain, which changes the crystalline lattice spacing and modifies the electronic properties of the metal. Understanding the role of elastic strain during catalytic reactions is thus crucial for catalyst design. Here, we show how single highly faceted Pt nanoparticles expand or contract upon interaction with different gas atmospheres using in situ nano-focused coherent X-ray diffraction imaging. We also demonstrate inter-particle heterogeneities, as they differ in development of strain under CO oxidation reaction conditions. The reported observations offer new insights into the design of catalysts exploiting strain effects.",

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doi = "10.1039/C8NR08414A",

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AU - Fernández, Sara

AU - Gao, Lu

AU - Hofmann, Jan Philipp

AU - Carnis, Jérôme

AU - Labat, Stéphane

AU - Chahine, Gilbert A.

AU - Van Hoof, Arno J.F.

AU - Verhoeven, M. W.G.M.

AU - Schülli, Tobias U.

AU - Hensen, Emiel J.M.

AU - Thomas, Olivier

AU - Richard, Marie Ingrid

PY - 2019/1/7

Y1 - 2019/1/7

N2 - The catalytic activity of metal nanoparticles can be altered by applying strain, which changes the crystalline lattice spacing and modifies the electronic properties of the metal. Understanding the role of elastic strain during catalytic reactions is thus crucial for catalyst design. Here, we show how single highly faceted Pt nanoparticles expand or contract upon interaction with different gas atmospheres using in situ nano-focused coherent X-ray diffraction imaging. We also demonstrate inter-particle heterogeneities, as they differ in development of strain under CO oxidation reaction conditions. The reported observations offer new insights into the design of catalysts exploiting strain effects.

AB - The catalytic activity of metal nanoparticles can be altered by applying strain, which changes the crystalline lattice spacing and modifies the electronic properties of the metal. Understanding the role of elastic strain during catalytic reactions is thus crucial for catalyst design. Here, we show how single highly faceted Pt nanoparticles expand or contract upon interaction with different gas atmospheres using in situ nano-focused coherent X-ray diffraction imaging. We also demonstrate inter-particle heterogeneities, as they differ in development of strain under CO oxidation reaction conditions. The reported observations offer new insights into the design of catalysts exploiting strain effects.

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EP - 338

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In situ structural evolution of single particle model catalysts under ambient pressure reaction conditions

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