In-Situ Thermometry Reveals Fragmentation Behavior Based on Local Temperature in α-Olefin Polymerization Catalysts

Joren M. Dorresteijn; Bas Terlingen; Koen W. Bossers; Thimo S. Jacobs; Yevkeni Wisse; Peter de Peinder; Virginie Cirriez; Alexandre Welle; Eelco T. C. Vogt; Florian Meirer; Bert M. Weckhuysen

doi:10.1021/jacs.4c11357

In-Situ Thermometry Reveals Fragmentation Behavior Based on Local Temperature in α-Olefin Polymerization Catalysts

Joren M. Dorresteijn, Bas Terlingen, Koen W. Bossers, Thimo S. Jacobs, Yevkeni Wisse, Peter de Peinder, Virginie Cirriez, Alexandre Welle, Eelco T. C. Vogt, Florian Meirer, Bert M. Weckhuysen^*

^*Corresponding author for this work

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

Abstract

Typical industrial olefin polymerization processes to produce both commodity and specialty polyolefin grades are mainly based on spherical, heterogeneous catalyst particles. During α-polymerization, heat from the exothermic reaction and pressure induced by the growing polymer chains on the catalyst particle lead to fragmentation, revealing active sites for further polymerization. To study these phenomena precisely and in-depth, we utilized a Nd-doped LaOCl-supported metallocene model system. This model catalyst can accurately display fluctuations in temperature with luminescence thermometry. During mild gas phase prepolymerization conditions, we observed a temperature difference of +43 °C and link this to the exothermicity of the ethylene polymerization reaction. In addition, the fragmentation behavior of the model catalyst was accurately monitored. The shell feature of the catalyst ruptured layer-by-layer, while the inner core fragmented via a bisectional fragmentation mechanism. We demonstrated that it is possible to probe the individual temperatures of multiple catalyst support particles within the field-of-view of the probe. This was correlated to structural changes and kinetics in an α-olefin polymerization catalyst. This powerful toolbox could be applied to different heterogeneous catalytic systems to correlate the temperature profile with morphological evolution.

Original language	English
Pages (from-to)	5642-5648
Number of pages	7
Journal	Journal of the American Chemical Society
Volume	147
Issue number	7
Early online date	10 Feb 2025
DOIs	https://doi.org/10.1021/jacs.4c11357
Publication status	Published - 19 Feb 2025

Bibliographical note

Publisher Copyright:
© 2025 The Authors. Published by American Chemical Society.

Funding

We acknowledge Coen Mulder and Helen de Waard (both from Utrecht University, UU) for performing the ICP-OES experiments; Liliane Peters (TotalEnergies) for performing DSC measurements; Joris Janssens (UU), Ramon Oord (UU), and Pascal Wijten (UU) for help during the buildup of the different setups used in this study; and Thomas van Swieten (UU) for fruitful discussions and help during the design of in situ thermometry experiments. We also thank Kim van Ommering (UU) for the feedback on the text revision. We acknowledge funding provided by TotalEnergies.

Funders	Funder number
TotalEnergies

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Dorresteijn, J. M., Terlingen, B., Bossers, K. W., Jacobs, T. S., Wisse, Y., de Peinder, P., Cirriez, V., Welle, A., Vogt, E. T. C., Meirer, F., & Weckhuysen, B. M. (2025). In-Situ Thermometry Reveals Fragmentation Behavior Based on Local Temperature in α-Olefin Polymerization Catalysts. Journal of the American Chemical Society, 147(7), 5642-5648. https://doi.org/10.1021/jacs.4c11357

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title = "In-Situ Thermometry Reveals Fragmentation Behavior Based on Local Temperature in α-Olefin Polymerization Catalysts",

abstract = "Typical industrial olefin polymerization processes to produce both commodity and specialty polyolefin grades are mainly based on spherical, heterogeneous catalyst particles. During α-polymerization, heat from the exothermic reaction and pressure induced by the growing polymer chains on the catalyst particle lead to fragmentation, revealing active sites for further polymerization. To study these phenomena precisely and in-depth, we utilized a Nd-doped LaOCl-supported metallocene model system. This model catalyst can accurately display fluctuations in temperature with luminescence thermometry. During mild gas phase prepolymerization conditions, we observed a temperature difference of +43 °C and link this to the exothermicity of the ethylene polymerization reaction. In addition, the fragmentation behavior of the model catalyst was accurately monitored. The shell feature of the catalyst ruptured layer-by-layer, while the inner core fragmented via a bisectional fragmentation mechanism. We demonstrated that it is possible to probe the individual temperatures of multiple catalyst support particles within the field-of-view of the probe. This was correlated to structural changes and kinetics in an α-olefin polymerization catalyst. This powerful toolbox could be applied to different heterogeneous catalytic systems to correlate the temperature profile with morphological evolution.",

author = "Dorresteijn, {Joren M.} and Bas Terlingen and Bossers, {Koen W.} and Jacobs, {Thimo S.} and Yevkeni Wisse and {de Peinder}, Peter and Virginie Cirriez and Alexandre Welle and Vogt, {Eelco T. C.} and Florian Meirer and Weckhuysen, {Bert M.}",

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Dorresteijn, JM, Terlingen, B, Bossers, KW, Jacobs, TS, Wisse, Y, de Peinder, P, Cirriez, V, Welle, A, Vogt, ETC , Meirer, F & Weckhuysen, BM 2025, 'In-Situ Thermometry Reveals Fragmentation Behavior Based on Local Temperature in α-Olefin Polymerization Catalysts', Journal of the American Chemical Society, vol. 147, no. 7, pp. 5642-5648. https://doi.org/10.1021/jacs.4c11357

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T1 - In-Situ Thermometry Reveals Fragmentation Behavior Based on Local Temperature in α-Olefin Polymerization Catalysts

AU - Dorresteijn, Joren M.

AU - Terlingen, Bas

AU - Bossers, Koen W.

AU - Jacobs, Thimo S.

AU - Wisse, Yevkeni

AU - de Peinder, Peter

AU - Cirriez, Virginie

AU - Welle, Alexandre

AU - Vogt, Eelco T. C.

AU - Meirer, Florian

AU - Weckhuysen, Bert M.

PY - 2025/2/19

Y1 - 2025/2/19

N2 - Typical industrial olefin polymerization processes to produce both commodity and specialty polyolefin grades are mainly based on spherical, heterogeneous catalyst particles. During α-polymerization, heat from the exothermic reaction and pressure induced by the growing polymer chains on the catalyst particle lead to fragmentation, revealing active sites for further polymerization. To study these phenomena precisely and in-depth, we utilized a Nd-doped LaOCl-supported metallocene model system. This model catalyst can accurately display fluctuations in temperature with luminescence thermometry. During mild gas phase prepolymerization conditions, we observed a temperature difference of +43 °C and link this to the exothermicity of the ethylene polymerization reaction. In addition, the fragmentation behavior of the model catalyst was accurately monitored. The shell feature of the catalyst ruptured layer-by-layer, while the inner core fragmented via a bisectional fragmentation mechanism. We demonstrated that it is possible to probe the individual temperatures of multiple catalyst support particles within the field-of-view of the probe. This was correlated to structural changes and kinetics in an α-olefin polymerization catalyst. This powerful toolbox could be applied to different heterogeneous catalytic systems to correlate the temperature profile with morphological evolution.

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In-Situ Thermometry Reveals Fragmentation Behavior Based on Local Temperature in α-Olefin Polymerization Catalysts

Abstract

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Funding

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