Thermoswitchable catalysis to inhibit and promote plastic flow in vitrimers

Van Lysebetten, Filip; Maes, Stephan; Winne, Johan; Du Prez, Filip

Thermoswitchable catalysis to inhibit and promote plastic flow in vitrimers

Filip Van Lysebetten, Stephan Maes (UGent) , Johan Winne (UGent) and Filip Du Prez (UGent)

(2024) CHEMICAL SCIENCE. 15(19). p.7061-7071

Author

Filip Van Lysebetten, Stephan Maes (UGent) , Johan Winne (UGent) and Filip Du Prez (UGent)

Organization

Department of Organic and Macromolecular Chemistry

Project

Circular Thermoset Materials: How to exploit Precision Engineered Macromolecules in their Bottom-up Design?
Sulfone derivatives - a new chemistry platform for the next generation of dynamic covalent materials
Cut-and-paste chemistry: from circular plastics to immunotherapeutics

Abstract

Acid-base catalysis is a common strategy to induce covalent bond exchanges in dynamic polymer networks. Strong acids or strong bases can promote rapid network rearrangements, and are simultaneously preferred catalysts for chemical reactions where maximum efficiency at the lowest possible temperature is aimed for. However, within the context of dynamic polymer networks, the incorporation of highly active catalysts can negatively affect the longer term application potential. Network dynamicity can diminish through catalyst ageing or quenching and highly active catalysts may prematurely activate bond exchanges, leading to dimensional instability and thus low creep resistance of the polymer networks. Herein, we present several examples where we explicitly explored weak acids (carboxylic acids) as catalysts for dynamic bond exchanges, using vinylogous urethanes (VU) as a well-understood protic acid catalysed vitrimer chemistry. Surprisingly, we have found that the sought-after long-term stability offered by a weak acid does not necessarily bring lower activity at high temperature. In fact, the weak acids show a remarkable thermoswitchable catalytic behaviour, going from an inactive hydrogen bonded state to an active state where the polymer matrix is protonated, with a profound impact on the network reactivity and rheology. Carboxylic acids with different electronic or steric environments show clear reactivity trends and their fine-tuning resulted in the most thermally responsive VU vitrimers studied to date. Our findings point out that catalyst choice and design for vitrimers is only poorly informed by catalyst performance in more traditional chemical reactions (in solvent), and that a more tailored catalyst design holds great promise for the field of vitrimers. We show that weaker acid catalysis has profound effects on the dynamicity of vinylogous urethane based polymer networks. Moreover, the dynamicity could be adjusted by changing electronic and steric parameters in the catalytic environment.

Keywords

COVALENT ADAPTABLE NETWORKS, ACID-BASE, POLYMER NETWORKS, INTERNAL CATALYSIS, PROTON-TRANSFER, BENZOIC-ACIDS, HYDROGEN-BOND, CHEMISTRY, EQUILIBRIA, REACTIVITY

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Citation

Please use this url to cite or link to this publication: http://hdl.handle.net/1854/LU-01J14W39HS0N3B8HCDPH9T72CK

MLA: Van Lysebetten, Filip, et al. “Thermoswitchable Catalysis to Inhibit and Promote Plastic Flow in Vitrimers.” CHEMICAL SCIENCE, vol. 15, no. 19, 2024, pp. 7061–71, doi:10.1039/d4sc00417e.
APA: Van Lysebetten, F., Maes, S., Winne, J., & Du Prez, F. (2024). Thermoswitchable catalysis to inhibit and promote plastic flow in vitrimers. CHEMICAL SCIENCE, 15(19), 7061–7071. https://doi.org/10.1039/d4sc00417e
Chicago author-date: Van Lysebetten, Filip, Stephan Maes, Johan Winne, and Filip Du Prez. 2024. “Thermoswitchable Catalysis to Inhibit and Promote Plastic Flow in Vitrimers.” CHEMICAL SCIENCE 15 (19): 7061–71. https://doi.org/10.1039/d4sc00417e.
Chicago author-date (all authors): Van Lysebetten, Filip, Stephan Maes, Johan Winne, and Filip Du Prez. 2024. “Thermoswitchable Catalysis to Inhibit and Promote Plastic Flow in Vitrimers.” CHEMICAL SCIENCE 15 (19): 7061–7071. doi:10.1039/d4sc00417e.
Vancouver: 1.
Van Lysebetten F, Maes S, Winne J, Du Prez F. Thermoswitchable catalysis to inhibit and promote plastic flow in vitrimers. CHEMICAL SCIENCE. 2024;15(19):7061–71.
IEEE: [1]
F. Van Lysebetten, S. Maes, J. Winne, and F. Du Prez, “Thermoswitchable catalysis to inhibit and promote plastic flow in vitrimers,” CHEMICAL SCIENCE, vol. 15, no. 19, pp. 7061–7071, 2024.

@article{01J14W39HS0N3B8HCDPH9T72CK,
  abstract     = {{Acid-base catalysis is a common strategy to induce covalent bond exchanges in dynamic polymer networks. Strong acids or strong bases can promote rapid network rearrangements, and are simultaneously preferred catalysts for chemical reactions where maximum efficiency at the lowest possible temperature is aimed for. However, within the context of dynamic polymer networks, the incorporation of highly active catalysts can negatively affect the longer term application potential. Network dynamicity can diminish through catalyst ageing or quenching and highly active catalysts may prematurely activate bond exchanges, leading to dimensional instability and thus low creep resistance of the polymer networks. Herein, we present several examples where we explicitly explored weak acids (carboxylic acids) as catalysts for dynamic bond exchanges, using vinylogous urethanes (VU) as a well-understood protic acid catalysed vitrimer chemistry. Surprisingly, we have found that the sought-after long-term stability offered by a weak acid does not necessarily bring lower activity at high temperature. In fact, the weak acids show a remarkable thermoswitchable catalytic behaviour, going from an inactive hydrogen bonded state to an active state where the polymer matrix is protonated, with a profound impact on the network reactivity and rheology. Carboxylic acids with different electronic or steric environments show clear reactivity trends and their fine-tuning resulted in the most thermally responsive VU vitrimers studied to date. Our findings point out that catalyst choice and design for vitrimers is only poorly informed by catalyst performance in more traditional chemical reactions (in solvent), and that a more tailored catalyst design holds great promise for the field of vitrimers.

We show that weaker acid catalysis has profound effects on the dynamicity of vinylogous urethane based polymer networks. Moreover, the dynamicity could be adjusted by changing electronic and steric parameters in the catalytic environment.}},
  author       = {{Van Lysebetten, Filip and Maes, Stephan and Winne, Johan and Du Prez, Filip}},
  issn         = {{2041-6520}},
  journal      = {{CHEMICAL SCIENCE}},
  keywords     = {{COVALENT ADAPTABLE NETWORKS,ACID-BASE,POLYMER NETWORKS,INTERNAL CATALYSIS,PROTON-TRANSFER,BENZOIC-ACIDS,HYDROGEN-BOND,CHEMISTRY,EQUILIBRIA,REACTIVITY}},
  language     = {{eng}},
  number       = {{19}},
  pages        = {{7061--7071}},
  title        = {{Thermoswitchable catalysis to inhibit and promote plastic flow in vitrimers}},
  url          = {{http://doi.org/10.1039/d4sc00417e}},
  volume       = {{15}},
  year         = {{2024}},
}

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Thermoswitchable catalysis to inhibit and promote plastic flow in vitrimers

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