兼具导热和自修复功能的聚合物复合材料

针对聚合物复合材料存在的结构受损导致导热和力学强度降低的问题,提出利用导热填料增强自修复聚合物,实现导热性能和力学强度的快速修复.通过对双(3-氨丙基)封端的聚二甲基硅氧烷(H2N-PDMS-NH2)进行端基改性,得到脲基嘧啶酮(UPy)双封端的聚二甲基硅氧烷(UPy-PDMS-UPy),于60℃下20 h后拉伸强度修复效率可达86.6%.进一步填充羟基化氮化硼(mBN)制备兼具自修复功能的导热复合材料,研究发现mBN的填充导致复合材料强度提高但韧性降低,对导热性能和自修复功能分别起积极和不利影响.当mBN含量为30 wt%时,热导率高达2.579 W·m^−1·K^−1,于60℃下40 h后拉伸强度修复效率达82.0%.红外热像仪显示,损伤处接触10 h后,mBN-30/UPy-PDMS-UPy上表面温度接近初始温度,展现出导热通路的修复特征,实现导热与自修复功能的兼备.

基于快速热释放功能的偶氮基光热材料

针对传统的偶氮储热材料仅能吸收紫外光,并且高储能密度的储热材料诱导放热温度高,放热速率低的问题,通过分子设计,在偶氮苯中引入具有吸电子性的噻唑杂环,与具有推电子性的甲氧基形成推拉电子结构.推拉电子结构的杂环偶氮苯分子具有快速回复和吸收紫光的特点.同时以石墨烯为模板制备储热复合材料,增加了分子间相互作用,从而使材料的储热密度达到了89 Wh/kg,半衰期为10 h,输出功率具有890 W/kg.材料在435 nm波长处有最大的吸收强度,实现了对紫光区域的吸收.该储热材料在60和80℃的刺激下分别达到了2.6和3.8℃的温差.通过温度刺激,储热材料释放的热能够使2种热致变色颜料(62℃下发生红色→无色,82℃下发生蓝色→无色)分别在60和80℃环境下发生明显的消色,通过不同温度刺激产生不同温差使得热致变色颜料发生颜色改变,实现了放热的可视化.

具有光热存储与释放功能的偶氮苯侧链接枝聚降冰片烯

将甲氧基和羧基取代偶氮苯共价接枝到开环易位聚合方法制备的聚降冰片烯侧链上,制备了具有光热存储与释放功能的偶氮基聚降冰片烯(PNB-Azo).结果表明,当偶氮苯在聚合物上的接枝密度为31%(偶氮苯与聚合物结构单元摩尔比)时,可获得具有良好柔韧性和自支撑性的光热膜,拉伸强度和最大应变分别可达21.5 MPa和120%.通过在波长365 nm的紫外充热后,PNB-Azo膜光热存储的能量密度可达34 Wh/kg.该薄膜在波长为550 nm的绿光照射和50°C条件下,能实现存储热量的可控释放,与未充热的膜相比,温差可达1.25℃.该结果为制备具有光热循环利用功能的柔性光热膜提供了材料基础.

基于快速热释放功能的相变偶氮苯/织物复合材料

针对偶氮基光敏分子存在放热速率慢和温度难以控制的难点,在分子结构设计基础上,采用氧化偶合法制备了具有固-液相变功能的4,4′-对-二正己基偶氮苯(AZO-L6).由于分子间作用力较低,偶氮苯分子呈现低熔、快异构化的特点,在发生反-顺异构化转变时大幅降低分子的熔点.固-液相变过程实现了光热能和相变焓的存储,在结构回复时同时放出储存的能量(231.8 kJ/kg),并将相变偶氮苯应用于可穿戴聚合物复合织物中.结果显示储能后的相变偶氮苯分子在蓝光(440 nm)刺激下在60 s内可将材料温度提升0.8℃,获得了具有自加热功能的可穿戴复合织物,为探索多功能自保温可穿戴装置提供了研究思路.

Structural Design and Application of Azo-based Supramolecular Polymer Systems

This article presents a brief overview of recent advances in azo-containing supramolecular systems.In literature,it has been shown that azo supramolecular polymers and their composite materials exhibit fast and intelligent responses to various external stimuli,such as temperature,pH change,redox reagents,ligands,coupling reagents,etc.In applications,these systems are widely used for molecular motors,shape memory,liquid crystal,solar thermal energy storage,signal transmission,intelligent encryption,and other purposes.Furthermore,these systems can function as key components for device upgrade processing.However,the design and rules of azo supramolecular polymers are still not supported by an exact theory.Information about the relationship between the spatial structure and behavior is lacking,and new supramolecular materials cannot be designed by adding functional moieties to known azo polymers.Based on the current research status,this review mainly summarizes the structural design principles as well as structures and applications of known azo supramolecules;meanwhile,it highlights the emerging development fields,recent advances,and prospects in fabricating sei住assembling intelligent supramolecular systems with azo supramolecular polymers as responsive units.The goal of this review is to bring new inspiration to researchers who want to optimize the chemical structure,steric conformation,electrostatic environment,and specific molecular functionalization.