材料科学
联锁
各向异性
复合材料
纳米技术
仿生学
消散
超分子化学
刚度
纳米-
复合数
弯曲
灵活性(工程)
人工肌肉
变形(气象学)
剪切(地质)
纳米复合材料
各向同性
导电体
垂直的
纳米尺度
制作
聚合物
小型化
稳健性(进化)
纳米纤维
超细纤维
抗弯刚度
柔性电子器件
纳米颗粒
小旋翼机
作者
Jiahao Kang,Xiaozheng Su,Piaopiao Zhou,Kun Yu,Zehang Du,Dong Shi,Yan Yu,Xiaolin Lyu,Zhigang Zou
标识
DOI:10.1002/adma.202511903
摘要
Ionogels have garnered significant attention in various cutting-edge fields due to their tunable mechanical properties and remarkable multifunctionality. However, current ionogels still struggle to achieve a combination of mechanical robustness and tissue-like anisotropy, hindering their application in next-generation intelligent biomimetic materials. Inspired by the anisotropic structure of tendons, we have embedded parallel-aligned rigid fiber bundles within a flexible ionogel to establish a tight interfacial bonding through supramolecular interlocking. This design enables the dispersion of stress and dissipation of energy through shear deformation of the ionogel in the parallel direction while maintaining high flexibility and stretchability in the perpendicular direction. Thus, tough anisotropic composite ionogels (ACIGs) can be constructed, which exhibit high strength, high modulus, as well as pronounced strength and stiffness anisotropies. The mechanical properties and anisotropies far surpass those of current anisotropic gel materials. Additionally, ACIG demonstrates excellent crack resistance, a wide operational temperature range, and high adhesiveness. It can serve as a biomimetic ligament to secure artificial joints, maintaining stability even after 10 000 bending cycles. Moreover, the conductive properties enable ACIG to function as a sensor for detecting joint movements and transmitting information, holding significant application potential in fields such as intelligent equipment and wearable devices.
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