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Rosin side chain type catalyst-free vitrimers with high cross-link density, mechanical strength, and thermal stability |
Yunpeng Shen1, Weishan Tang1, Jinyang Li1, Zhijun Ke1, Lirong Liao1, Peng Yang1, Yuntao Lu1, Xiaoping Rao1,2() |
1. College of Chemical Engineering, Huaqiao University, Xiamen 361021, China 2. Academy of Advanced Carbon Conversion Technology, Huaqiao University, Xiamen 361021, China |
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Abstract The emergence of vitrimer, a new class of polymer materials can address the problem of recyclability, reprocess ability and recyclability of thermosetting plastics. Rosin, a natural product, is an ideal raw material for the preparation of polymers in a more sustainable way. Nevertheless, due to the huge steric hindrance caused by the hydrogenated phenanthrene ring structure, the cross-link density of materials is frequently lowered. In this study, hydrogenated rosin was adopted for preparing hydrogenated rosin side-chain type diacids, which were reacted with mixed epoxy to obtain rosin side-chain type vitrimers. It was completely characterized by differential scanning calorimetry test, thermogravimetric analysis, shape memory test and self-healing test. The prepared vitrimers exhibited good self-healing properties, excellent heat resistance (Td = 352 °C) as well as high mechanical properties (tensile strength of 46.75 MPa). The tricyclic diterpene structure of rosin was introduced into the side chain in order to avoid the reduction of cross-link density resulting from the huge steric hindrance of the rigid tricyclic hydrophenylene skeleton. Vitrimers can undergo dynamic transesterification reaction without external catalysts due to the autocatalytic effect of tertiary amines from epoxy. Moreover, our work expanded the application field of rosin, increased the added value of rosin, and provided a novel method for preparing rosin-based vitrimers with ideal properties.
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Keywords
vitrimers
rosin
catalyst-free
high mechanical properties
dynamic transesterification reaction
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Corresponding Author(s):
Xiaoping Rao
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About author: * These authors contributed equally to this work. |
Just Accepted Date: 13 December 2022
Online First Date: 12 April 2023
Issue Date: 29 August 2023
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