Internal catalysis for dynamic covalent chemistry applications and polymer science

Strong covalent chemical bonds that can also be reversed, cleaved or exchanged are the subject of so-called dynamic covalent chemistry (DCC). Applications range from classical protective groups in organic chemistry and cleavable linkers for solid phase synthesis, to more modern applications in dynam...

Full description

Saved in:
Bibliographic Details
Published inChemical Society reviews Vol. 49; no. 23; pp. 8425 - 8438
Main Authors Van Lijsebetten, Filip, Holloway, Joshua O, Winne, Johan M, Du Prez, Filip E
Format Journal Article
LanguageEnglish
Published England Royal Society of Chemistry 07.12.2020
Subjects
area
Bonding strength
cans
Catalysis
catalysts
catalytic activity
chemical bonding
Chemical bonds
Covalence
design
enzymatic reactions
Exchanging
Functional groups
libraries
moieties
Organic chemistry
Polymers
Properties (attributes)
Self healing materials
society
Solid phase synthesis
Solid phases
synthesis
yields
Online AccessGet full text

Cover

More Information
Summary:Strong covalent chemical bonds that can also be reversed, cleaved or exchanged are the subject of so-called dynamic covalent chemistry (DCC). Applications range from classical protective groups in organic chemistry and cleavable linkers for solid phase synthesis, to more modern applications in dynamic compound libraries and adaptive materials. Interest in dynamic, reversible or responsive chemistries has risen in particular in the last few decades for the design and synthesis of new DCC-based polymer materials. Implementation of DCC in polymers yields materials with unique combinations of properties and in some cases even unprecedented properties for covalent materials, such as self-healing materials, covalent adaptable networks (CANs) and vitrimers. In particular, the incorporation of DCC in polymer materials aims to find a balance between a swift and triggerable reactivity, combined with a high degree of intrinsic robustness and stability. Applying harsh conditions, highly active catalysts or highly reactive bonding groups, as is done in classical DCC, is often not feasible or desirable, as it can damage the polymer's integrity, leading to loss of function and properties. In this context, so-called internally catalysed DCC platforms have started to receive more interest in this area. This approach relies on the relative proximity and orientation of common functional groups, which can influence a chemical exchange reaction in a subtle but significant way. This approach mimicks the strategies found in enzymic reactions, and is known in classical organic chemistry as neighbouring group participation (NGP). The use of internal catalysis or NGP within polymer material science has proven to be a highly attractive strategy. This tutorial review will outline examples showing the scope, advantages and pitfalls of using internal catalysis within different DCC applications, ranging from small molecules to dynamic polymer materials. In this review, we provide a concise analysis of internal catalysis as an attractive design principle to combine chemical robustness with reactivity in dynamic covalent chemistry applications and a material context.
Bibliography:Prof. Dr Johan Winne was appointed as an assistant-professor at Ghent University in 2015. There, he leads a research group of organic synthetic chemists that share his fascination for the chemistry of natural products, heterocycles and cycloadditions. Apart from tackling fundamental problems in organic reactivity and explorative reaction design for the synthesis of complex molecules, he has picked up a keen interest in applications of organic reactivity within polymer chemistry, through joint projects with Filip Du Prez and his research group in the design and exploration of novel materials based on dynamic covalent chemistries.
www.PCR.UGent.be
within the Centre of Macromolecular Chemistry (CMaC) at Ghent University (Belgium) in which about 25 researchers are dealing with the design of dynamic/renewable polymer materials, the development of new polymer structures such as sequence-defined polymers and the exploration of powerful functionalization methods in polymer chemistry. He is author of 330 peer-reviewed publications, 14 patents, 10 book chapters and (co-)chairman of more than 10 (inter)national conferences on polymer chemistry related topics. Since 2018, he is associate editor of Polymer Chemistry.
Dr Joshua Holloway obtained his Master of Chemistry (MChem) degree from the University of Reading (UK) in 2015 before obtaining his PhD in Chemistry from Ghent University (Belgium), in 2019, which was funded by a Marie Sk odowska-Curie scholarship. His PhD thesis, entitled "From Sequence-Defined Macromolecules to Macromolecular Pin Codes," investigated the synthesis of well-defined oligomers using click chemistry platforms and was carried out under the supervision of Prof. Filip Du Prez. He is now a Postdoctoral Researcher in the Polymer Chemistry Research group, Ghent University, working in the area of vitrimers and dynamic networks.
Filip Van Lijsebetten obtained his Master's degree in Chemistry in 2019 from Ghent University (Belgium), performing his thesis on sequence-defined macromolecules in the group of Prof. Filip Du Prez. In October 2019, he received a PhD scholarship from the Research Foundation Flanders (FWO) to work on the development of industrially applicable dynamic polymer materials. One of the main goals of his work, is to tackle (re)processability and recyclability challenges currently observed within crosslinked and highly viscous polymers.
Prof. Dr Filip Du Prez is since 1999 heading the Polymer Chemistry Research Group
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 14
content type line 23
ISSN:0306-0012
1460-4744
1460-4744
DOI:10.1039/d0cs00452a