Dynamic restructuring of supported metal nanoparticles and its implications for structure insensitive catalysis

Vogt, Charlotte; Meirer, Florian; Monai, Matteo; Groeneveld, Esther; Ferri, Davide; Santen, Rutger A.; Nachtegaal, Maarten; Unocic, Raymond R.; Frenkel, Anatoly I.; Weckhuysen, Bert M.

Dynamic restructuring of supported metal nanoparticles and its implications for structure insensitive catalysis

Charlotte Vogt, Florian Meirer, Matteo Monai, Esther Groeneveld, Davide Ferri, Rutger A. Santen, Maarten Nachtegaal, Raymond R. Unocic, Anatoly I. Frenkel and Bert M. Weckhuysen ()
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Charlotte Vogt: Utrecht University
Florian Meirer: Utrecht University
Matteo Monai: Utrecht University
Esther Groeneveld: BASF Nederland B.V.
Davide Ferri: Paul Scherrer Institute (PSI)
Rutger A. Santen: Eindhoven University of Technology
Maarten Nachtegaal: Paul Scherrer Institute (PSI)
Raymond R. Unocic: Oak Ridge National Laboratory
Anatoly I. Frenkel: Stony Brook University
Bert M. Weckhuysen: Utrecht University

Nature Communications, 2021, vol. 12, issue 1, 1-10

Abstract: Abstract Some fundamental concepts of catalysis are not fully explained but are of paramount importance for the development of improved catalysts. An example is the concept of structure insensitive reactions, where surface-normalized activity does not change with catalyst metal particle size. Here we explore this concept and its relation to surface reconstruction on a set of silica-supported Ni metal nanoparticles (mean particle sizes 1–6 nm) by spectroscopically discerning a structure sensitive (CO2 hydrogenation) from a structure insensitive (ethene hydrogenation) reaction. Using state-of-the-art techniques, inter alia in-situ STEM, and quick-X-ray absorption spectroscopy with sub-second time resolution, we have observed particle-size-dependent effects like restructuring which increases with increasing particle size, and faster restructuring for larger particle sizes during ethene hydrogenation while for CO2 no such restructuring effects were observed. Furthermore, a degree of restructuring is irreversible, and we also show that the rate of carbon diffusion on, and into nanoparticles increases with particle size. We finally show that these particle size-dependent effects induced by ethene hydrogenation, can make a structure sensitive reaction (CO2 hydrogenation), structure insensitive. We thus postulate that structure insensitive reactions are actually apparently structure insensitive, which changes our fundamental understanding of the empirical observation of structure insensitivity.

Date: 2021
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DOI: 10.1038/s41467-021-27474-3

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