Issue 28, 2022

Molecularly engineered dual-crosslinked elastomer vitrimers with superior strength, improved creep resistance, and retained malleability

Abstract

It is very challenging to prepare elastomer vitrimers that are both robust and dimensionally stable in service. To address this issue, we have initiated a multi-phase design of elastomer vitrimers by incorporating quadruple hydrogen bonds (H-bonds) into vitrimer networks. Specifically, commercialized styrene–butadiene rubber (SBR) was functionalized with the synthesized 5-benzyl-3,6-dioxo-2-piperazineacetic acid (DKP) to introduce amide functionalities, which was then crosslinked by dimercapto-borate via thiol–ene “click” chemistry. The H-bonds between amide moieties functioned as sacrificial units, which could undergo reversible breakage and recombination events, and therefore improve the modulus, ultimate strength, and toughness simultaneously. Moreover, with an aromatic ring and a symmetrical amide group in the structure, the grafted DKP could self-assemble via hydrogen bonds, leading to the formation of a microphase-separated structure in the elastomer matrix. Besides, the creep resistance was improved as the H-bonds were physical crosslinks that imposed additional constraints on chain segment diffusion. Nevertheless, the reprocessability of the network was not affected as the H-bonds and boronic ester crosslinks could dissociate and exchange at elevated temperatures, respectively.

Graphical abstract: Molecularly engineered dual-crosslinked elastomer vitrimers with superior strength, improved creep resistance, and retained malleability

Supplementary files

Article information

Article type
Paper
Submitted
16 Apr 2022
Accepted
19 Jun 2022
First published
22 Jun 2022

Polym. Chem., 2022,13, 4144-4153

Molecularly engineered dual-crosslinked elastomer vitrimers with superior strength, improved creep resistance, and retained malleability

L. Wang, Y. Liu, Y. Qiao, Y. Wang, Z. Cui, S. Zhu, F. Dong, S. Fang and A. Du, Polym. Chem., 2022, 13, 4144 DOI: 10.1039/D2PY00489E

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