材料科学
韧性
超分子化学
共价键
断裂韧性
极限抗拉强度
纳米技术
氢键
聚乙二醇
弹性体
聚氨酯
聚合物
相(物质)
超分子聚合物
材料设计
模块化设计
复合材料
纳米颗粒
结构材料
自愈水凝胶
聚合物网络
相变
泄漏(经济)
网络共价键合
智能材料
热的
相变
热稳定性
延伸率
潜热
作者
Youlong Zhao,Siyu Chen,Silong Chen,Pengfei Si,Lijun Shi,Feng Ya,Yuan Lei,Liang Jiang,Jingxin Lei,Xiaowei Fu
标识
DOI:10.1021/acs.chemmater.6c00110
摘要
Conventional solid–solid phase change materials (PCMs) based on covalent cross-linking effectively address leakage issues but suffer from a lack of high toughness and self-healing capability. To overcome these limitations, a high-strength, toughness self-healing phase change material (SHPCM) was developed by constructing a dynamic supramolecular network. This was achieved through the synergistic combination of reversible disulfide bonds and hierarchical hydrogen bonds within a polyethylene glycol (PEG)-based polyurethane framework. The resulting material exhibits a solid–solid phase transition with a high latent heat of 98.4 J·g –1, along with superior mechanical properties, including a tensile strength of 23.28 ± 1.45 MPa, an elongation at break of 1468.02 ± 105.36%, and a fracture energy of 238.27 ± 35.31 MJ·m –3 . It also demonstrates high thermal reliability and stability. Critically, the dynamic supramolecular network endows the material with outstanding self-healing performance, achieving an efficiency of 94.93%. This unique integration of thermal energy storage, robust mechanical strength, and recyclability positions this SHPCM as a promising multifunctional material for advanced thermal-management applications, with potential for modular construction and extended service life.
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