Catalyst-free gallic acid-based epoxy vitrimers with reprocessability and high glass transition temperature

IF 4.1 2区 化学 Q2 POLYMER SCIENCE
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引用次数: 0

Abstract

General approaches for preparing epoxy vitrimers required lots of catalysts to accelerate transesterification to form the cross-linked network and the residual catalyst not only resulted in toxicity but also poor compatibility with other components. Herein, a green and facile strategy for preparing gallic acid epoxy resin (GA-EP) was developed under catalyst-free condition using renewable gallic acid, xylitol and hexahydro 4-methylphthalic anhydride (MHHPA) as feedstocks. The results indicated that the bio-based epoxy vitrimer had higher glass transition temperature (122 °C), satisfactory mechanical, thermal and degradation properties compared to neat Bisphenol A-based epoxy vitrimer. Furthermore, recycled GA-EP was ground into powder and added to the fresh resin to investigate its reusability. Compared to the original, the recycled epoxy vitrimer system demonstrated comparable performance, except for minor reductions in glass transition temperature (Tg) and modulus, likely stemming from the inherent inhomogeneity of the reprocessed material. This work provides a new approach to the production of high Tg bio-based epoxy vitrimers without adding any catalyst.

Abstract Image

具有再加工性和高玻璃化转变温度的无催化剂没食子酸基环氧玻璃rimers
制备环氧树脂缩微体的一般方法需要使用大量催化剂来加速酯交换反应以形成交联网络,残留的催化剂不仅会产生毒性,而且与其他成分的兼容性也很差。本文以可再生的没食子酸、木糖醇和六氢-4-甲基邻苯二甲酸酐(MHHPA)为原料,开发了一种在无催化剂条件下制备没食子酸环氧树脂(GA-EP)的绿色简便策略。结果表明,与纯双酚 A 型环氧树脂玻璃基三聚体相比,生物基环氧树脂玻璃基三聚体具有更高的玻璃化转变温度(122 °C)、令人满意的机械性能、热性能和降解性能。此外,还将回收的 GA-EP 磨成粉末并添加到新鲜树脂中,以研究其重复使用性。与原来的环氧树脂相比,回收的环氧树脂三聚体系统表现出相当的性能,只是玻璃化转变温度(T)和模量略有降低,这可能是由于再加工材料固有的不均匀性造成的。这项工作为在不添加任何催化剂的情况下生产高 T 值的生物基环氧树脂玻璃rimers 提供了一种新方法。
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来源期刊
Polymer
Polymer 化学-高分子科学
CiteScore
7.90
自引率
8.70%
发文量
959
审稿时长
32 days
期刊介绍: Polymer is an interdisciplinary journal dedicated to publishing innovative and significant advances in Polymer Physics, Chemistry and Technology. We welcome submissions on polymer hybrids, nanocomposites, characterisation and self-assembly. Polymer also publishes work on the technological application of polymers in energy and optoelectronics. The main scope is covered but not limited to the following core areas: Polymer Materials Nanocomposites and hybrid nanomaterials Polymer blends, films, fibres, networks and porous materials Physical Characterization Characterisation, modelling and simulation* of molecular and materials properties in bulk, solution, and thin films Polymer Engineering Advanced multiscale processing methods Polymer Synthesis, Modification and Self-assembly Including designer polymer architectures, mechanisms and kinetics, and supramolecular polymerization Technological Applications Polymers for energy generation and storage Polymer membranes for separation technology Polymers for opto- and microelectronics.
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