Visualizing the Structure, Composition and Activity of Single Catalyst Particles for Olefin Polymerization and Polyolefin Decomposition

Maximilian J. Werny; Florian Meirer; Bert M. Weckhuysen

doi:10.1002/anie.202306033

Visualizing the Structure, Composition and Activity of Single Catalyst Particles for Olefin Polymerization and Polyolefin Decomposition

Maximilian J. Werny, Florian Meirer^*, Bert M. Weckhuysen^*

^*Corresponding author for this work

Research output: Contribution to journal › Review article › peer-review

Abstract

The structural and morphological characterization of individual catalyst particles for olefin polymerization, as well as for the reverse process of polyolefin decomposition, can provide an improved understanding for how these catalyst materials operate under relevant reaction conditions. In this review, we discuss an emerging analytical toolbox of 2D and 3D chemical imaging techniques that is suitable for investigating the chemistry and reactivity of related catalyst systems. While synchrotron-based X-ray microscopy still provides unparalleled spatial resolutions in 2D and 3D, a number of laboratory-based techniques, most notably focused ion beam-scanning electron microscopy, confocal fluorescence microscopy, infrared photoinduced force microscopy and laboratory-based X-ray nano-computed tomography, have helped to significantly expand the arsenal of analytical tools available to scientists in heterogeneous catalysis and polymer science. In terms of future research, the review outlines the role and impact of in situ and operando (spectro−)microscopy experiments, involving sophisticated reactors as well as online reactant and product analysis, to obtain real-time information on the formation, decomposition, and mobility of polymer phases within single catalyst particles. Furthermore, the potential of fluorescence microscopy, X-ray microscopy and optical microscopy is highlighted for the high-throughput characterization of olefin polymerization and polyolefin decomposition catalysts. By combining these chemical imaging techniques with, for example, chemical staining methodologies, selective probe molecules as well as particle sorting approaches, representative structure–activity relationships can be derived at the level of single catalyst particles.

Original language	English
Article number	e202306033
Journal	Angewandte Chemie - International Edition
Volume	63
Issue number	6
Early online date	2 Oct 2023
DOIs	https://doi.org/10.1002/anie.202306033
Publication status	Published - 5 Feb 2024

Bibliographical note

Publisher Copyright:
© 2023 The Authors. Angewandte Chemie International Edition published by Wiley-VCH GmbH.

Funding

. Maximilian J. Werny graduated in 2018 with a M.Sc. in Inorganic Chemistry and Catalysis from the Technical University of Munich (TUM, Germany). Since then, he has been investigating structure–activity‐morphology relationships in industrial‐grade olefin polymerization catalysts in the group of Prof. Bert Weckhuysen (Utrecht University, The Netherlands) using advanced microscopy and spectroscopy techniques. His research is funded by the Dutch Polymer Institute (DPI, Eindhoven, The Netherlands) and involves collaborations with several research groups in Italy and Germany. He recently obtained his PhD degree from Utrecht University The research was funded by a grant from the Dutch Polymer Institute (DPI, P.O. Box 902, 5600 AX Eindhoven, The Netherlands) and represents a part of the Research Program of DPI project no. 813. F.M. (Utrecht University, UU) acknowledges additional funding from a Netherlands Organization for Scientific Research (NWO) VIDI grant (723.015.007). We further acknowledge the European Synchrotron Radiation Facility (ESRF) for provision of the synchrotron radiation facilities, more specifically beamline ID16B, to measure the data shown in Figure 10A . Julie Villanova (ESRF), Victor Vanpeene (ESRF), Luca Carnevale (University of Twente), Rafael Mayorga‐González (UU) and Caroline Versluis (UU) are acknowledged for their experimental support at beamline ID16B (ESRF). Ina Vollmer (UU) and Michael Jenks (UU) are thanked for providing the FCC and ECAT particles for the holotomography measurements at ID16B. Thomas Hartman (UU) is acknowledged for the cover image. The research was funded by a grant from the Dutch Polymer Institute (DPI, P.O. Box 902, 5600 AX Eindhoven, The Netherlands) and represents a part of the Research Program of DPI project no. 813. F.M. (Utrecht University, UU) acknowledges additional funding from a Netherlands Organization for Scientific Research (NWO) VIDI grant (723.015.007). We further acknowledge the European Synchrotron Radiation Facility (ESRF) for provision of the synchrotron radiation facilities, more specifically beamline ID16B, to measure the data shown in Figure 10A. Julie Villanova (ESRF), Victor Vanpeene (ESRF), Luca Carnevale (University of Twente), Rafael Mayorga-González (UU) and Caroline Versluis (UU) are acknowledged for their experimental support at beamline ID16B (ESRF). Ina Vollmer (UU) and Michael Jenks (UU) are thanked for providing the FCC and ECAT particles for the holotomography measurements at ID16B. Thomas Hartman (UU) is acknowledged for the cover image.

Funders	Funder number
Victor Vanpeene
Department of Primary Industries
Dutch Polymer Institute	813
European Synchrotron Radiation Facility
University of Twente
Nederlandse Organisatie voor Wetenschappelijk Onderzoek	723.015.007

Keywords

Catalysis
Catalyst Fragmentation
Chemical Imaging
Olefin Depolymerization
Olefin Polymerization

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Angew Chem Int Ed - 2023 - Werny - Visualizing the Structure Composition and Activity of Single Catalyst Particles forFinal published version, 4.29 MBLicence: CC BY

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abstract = "The structural and morphological characterization of individual catalyst particles for olefin polymerization, as well as for the reverse process of polyolefin decomposition, can provide an improved understanding for how these catalyst materials operate under relevant reaction conditions. In this review, we discuss an emerging analytical toolbox of 2D and 3D chemical imaging techniques that is suitable for investigating the chemistry and reactivity of related catalyst systems. While synchrotron-based X-ray microscopy still provides unparalleled spatial resolutions in 2D and 3D, a number of laboratory-based techniques, most notably focused ion beam-scanning electron microscopy, confocal fluorescence microscopy, infrared photoinduced force microscopy and laboratory-based X-ray nano-computed tomography, have helped to significantly expand the arsenal of analytical tools available to scientists in heterogeneous catalysis and polymer science. In terms of future research, the review outlines the role and impact of in situ and operando (spectro−)microscopy experiments, involving sophisticated reactors as well as online reactant and product analysis, to obtain real-time information on the formation, decomposition, and mobility of polymer phases within single catalyst particles. Furthermore, the potential of fluorescence microscopy, X-ray microscopy and optical microscopy is highlighted for the high-throughput characterization of olefin polymerization and polyolefin decomposition catalysts. By combining these chemical imaging techniques with, for example, chemical staining methodologies, selective probe molecules as well as particle sorting approaches, representative structure–activity relationships can be derived at the level of single catalyst particles.",

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AB - The structural and morphological characterization of individual catalyst particles for olefin polymerization, as well as for the reverse process of polyolefin decomposition, can provide an improved understanding for how these catalyst materials operate under relevant reaction conditions. In this review, we discuss an emerging analytical toolbox of 2D and 3D chemical imaging techniques that is suitable for investigating the chemistry and reactivity of related catalyst systems. While synchrotron-based X-ray microscopy still provides unparalleled spatial resolutions in 2D and 3D, a number of laboratory-based techniques, most notably focused ion beam-scanning electron microscopy, confocal fluorescence microscopy, infrared photoinduced force microscopy and laboratory-based X-ray nano-computed tomography, have helped to significantly expand the arsenal of analytical tools available to scientists in heterogeneous catalysis and polymer science. In terms of future research, the review outlines the role and impact of in situ and operando (spectro−)microscopy experiments, involving sophisticated reactors as well as online reactant and product analysis, to obtain real-time information on the formation, decomposition, and mobility of polymer phases within single catalyst particles. Furthermore, the potential of fluorescence microscopy, X-ray microscopy and optical microscopy is highlighted for the high-throughput characterization of olefin polymerization and polyolefin decomposition catalysts. By combining these chemical imaging techniques with, for example, chemical staining methodologies, selective probe molecules as well as particle sorting approaches, representative structure–activity relationships can be derived at the level of single catalyst particles.

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Visualizing the Structure, Composition and Activity of Single Catalyst Particles for Olefin Polymerization and Polyolefin Decomposition

Abstract

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Keywords

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