Solvent-free Synthesis of Alkynyl-Based Biobased Benzoxazine Resins with Excellent Heat Resistance

The synthesis of high-performance biomass benzoxazine resin by a solvent-free method is of great significance for environmental sustainability and practical application in the industrial field. In this paper, biobased eugenol and magnolol with additional allyl cross-linking sites were taken as pheno...

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Published in:ACS applied polymer materials 2023-04, Vol.5 (4), p.3015-3022
Main Authors: Sha, Xin-Long, Fei, Pengyu, Shen, Binxin, Chen, Jue, Liu, Zongtang, Sun, Yufeng, Miao, Jia-Tao
Format: Article
Language:English
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Summary:The synthesis of high-performance biomass benzoxazine resin by a solvent-free method is of great significance for environmental sustainability and practical application in the industrial field. In this paper, biobased eugenol and magnolol with additional allyl cross-linking sites were taken as phenol sources, and 3-aminophenylacetylene with alkynyl cross-linking sites was used as an amine source to prepare two biomass benzoxazine monomers E-apa and M-apa, and the corresponding cured resins poly­(E-apa) and poly­(M-apa) were prepared through a certain curing process. The comprehensive properties of the cured resins were studied. The results show that the glass-transition temperature (T g) of poly­(M-apa) is as high as over 400 °C, which is higher than that of poly­(E-apa) (215 °C), as well as the T g values of the typical biobased heat-resistant benzoxazine resins reported so far. At the same time, the initial thermal decomposition temperature (T di) of poly­(M-apa) (441 °C) is higher than that of poly­(E-apa) (373 °C), showing better thermostability. In addition, poly­(M-apa) also exhibits better mechanical properties including higher storage modulus and tensile strength (5.03 GPa, measured at 25 °C, and 48.0 ± 2.2 MPa, respectively) than poly­(E-apa) (3.93 GPa and 37.5 ± 1.5 MPa, respectively). Besides, poly­(M-apa) performs better in flame retardancy. The better comprehensive properties of poly­(M-apa) are based on the combined action of multiple cross-linking sites and rigid phenol sources.
ISSN:2637-6105
2637-6105
DOI:10.1021/acsapm.3c00183