Heat-resistant and robust biobased benzoxazine resins developed with a green synthesis strategy

Using eco-friendly methods to prepare high-performance thermosetting resins is of great significance for cutting-edge industrial fields and sustainable development. In this article, using isoeugenol and vanillin as the phenol source, 3-aminophenyl acetylene as the amine source, the propylene-termina...

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Veröffentlicht in:	Polymer chemistry 2021-01, Vol.12 (3), p.432-438
Hauptverfasser:	Sha, Xin-Long, Yuan, Li, Liang, Guozheng, Gu, Aijuan
Format:	Artikel
Sprache:	eng
Schlagworte:	Acetylene Aldehydes Benzoxazines Glass transition temperature Monomers Phenols Polymer chemistry Polymers Propylene Sustainable development Synthesis Thermal decomposition Thermosetting resins Vanillin
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container_title	Polymer chemistry
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creator	Sha, Xin-Long Yuan, Li Liang, Guozheng Gu, Aijuan
description	Using eco-friendly methods to prepare high-performance thermosetting resins is of great significance for cutting-edge industrial fields and sustainable development. In this article, using isoeugenol and vanillin as the phenol source, 3-aminophenyl acetylene as the amine source, the propylene-terminated benzoxazine monomer IE-apa and aldehyde-terminated benzoxazine monomer V-apa were synthesized with a green strategy in the whole synthesis and purification processes. After curing the two monomers, two biobased benzoxazine resins poly(IE-apa) and poly(V-apa) were obtained, and their comprehensive properties were investigated. The results show that poly(IE-apa) and poly(V-apa) have not only high glass transition temperatures (293 °C and 304 °C), but also high storage moduli (3.89 GPa and 3.65 GPa), initial thermal decomposition temperatures (395 °C and 393 °C) and tensile strengths (66.7 ± 2.2 MPa and 59.0 ± 3.2 MPa), and both resins exhibit the best overall performance among all biobased benzoxazine resins from mono-phenols. The high performance of the resins is attributed to the specific structure of the benzoxazine resins, that is, the synergistic interaction between alkynyl and propylene or aldehyde groups. Two high-performance biobased benzoxazine resins from mono-phenols are developed with a green synthesis strategy.
doi_str_mv	10.1039/d0py01529f
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The high performance of the resins is attributed to the specific structure of the benzoxazine resins, that is, the synergistic interaction between alkynyl and propylene or aldehyde groups. 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subjects	Acetylene Aldehydes Benzoxazines Glass transition temperature Monomers Phenols Polymer chemistry Polymers Propylene Sustainable development Synthesis Thermal decomposition Thermosetting resins Vanillin
title	Heat-resistant and robust biobased benzoxazine resins developed with a green synthesis strategy
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