聚脲
弹性体
材料科学
复合材料
刚度
刚度(电磁)
稳健性(进化)
模数
氢
氢键
相(物质)
弹性模量
机械系统
工作(物理)
剪切模量
动态模量
机械强度
动态力学分析
分子动力学
合理设计
纳米技术
软质材料
聚合物
智能材料
杨氏模量
结构刚度
微观力学
作者
Tianyu Wang,Chenxi Huyan,Qiuzhen Chen,Xiang Han,Fahu Yang,Zibi Wang,Changxiang Guo,Dong Liu,Fei Chen
出处
期刊:Soft Matter
[Royal Society of Chemistry]
日期:2026-01-01
卷期号:22 (5): 1151-1160
被引量:2
摘要
High-performance elastomers always suffer from the trade-off between the ability of self-healing and mechanical stiffness. Here we report a hierarchical, synergistic hydrogen-bonding design that overcomes this trade-off. By integrating quadruple hydrogen bonds with moderately dynamic hydrogen-bond clusters within the hard domains of polyurea, we create a dual-dynamic, decoupled phase architecture that simultaneously imparts rigidity and enables reversible molecular reconfiguration. This interplay of strong and dynamic interactions generates robust hard domains that reinforce mechanical strength while preserving rapid, thermally activated self-healing. The resulting polyurea exhibits near-complete recovery of mechanical performance (≈100% at 80 °C after 8 h) together with a high Young's modulus of 24.2 MPa. This work demonstrates a rational strategy to reconcile the conflicting demands of self-healing and stiffness in polymeric materials through a hierarchical synergistic hydrogen-bonding system.
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