Zidie Song, Li Liu, Pengbo Zhang, Kangle Xue, Zibo Hua, Tao You, Yiqi Wu, Hong Cui, Zhen Hu and Yudong Huang
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引用次数: 0
摘要
可降解环氧树脂旨在解决传统环氧树脂造成的环境污染问题。然而,将动态共价键的可降解性纳入可降解树脂的设计中,往往会影响材料的刚性和耐热性,使其不太适合高温应用,如深空探测中使用的材料。本文介绍了一种完全基于生物的创新型环氧单体。它的循环刚性动态键使其具有较高的拉伸模量(4.06 GPa)、玻璃化转变温度(Tg=240 °C)、显著的抗蠕变性(180 °C时可完全恢复形状)和出色的降解性,在50 °C时只需60分钟即可完全溶解于0.1 M HCl溶液中。二缩醛是通过香兰素与木糖醇在酸性条件下反应制备的。然后与生物衍生的环氧氯丙烷反应,制备出具有羟基和双环缩醛结构的生物基多功能环氧单体,这标志着一种生态友好型聚合物合成的新策略。然后用固化剂固化这种单体,形成环氧交联网络。这种环保型原材料很容易获得,而合成的交联网络结构具有极高的性能。这使其成为一种可用于深空探测和其他恶劣环境的潜在材料,并为合成适用于极端条件的化学可降解环氧树脂提供了一个基准。
Fully bio-based acetal diepoxy monomer with high modulus, good thermal stability and readily degradability†
Degradable epoxy resins are designed to address the environmental pollution caused by traditional epoxy resins. However, incorporating the degradability of dynamic covalent bonds in the design of degradable resins often compromises the rigidity and heat resistance of the material, rendering it less suitable for high-temperature applications, such as those used in deep space exploration. This paper presents the creation of an innovative, entirely bio-based epoxy monomer. Its cyclic rigid dynamic bonds confer a high tensile modulus (4.06 GPa), glass transition temperature (Tg = 240 °C), notable creep resistance with full shape recovery at 180 °C, and remarkable degradability, dissolving entirely in a 1 M HCl solution in just 60 minutes at 50 °C. The preparation of the diacetal was accomplished by reacting vanillin with xylitol under acidic conditions. This was followed by a reaction with bio-derived epichlorohydrin to produce bio-based, multifunctional epoxy monomers featuring hydroxyl groups and bicyclic acetal structures, representing a new strategy for eco-friendly polymer synthesis. This monomer was then cured with a hardener to create an epoxy crosslinked network. The eco-friendly raw materials are easily obtainable, and the synthesized cross-linked network structure is exceptionally high-performing. This makes it a potential material for use in deep space exploration and other tough environments, and it provides a benchmark for synthesizing chemically degradable epoxy resins suitable for extreme conditions.
期刊介绍:
Polymer Chemistry welcomes submissions in all areas of polymer science that have a strong focus on macromolecular chemistry. Manuscripts may cover a broad range of fields, yet no direct application focus is required.