材料科学
韧性
纳米晶材料
丝素
磁滞
复合材料
无定形固体
生物相容性
量子纠缠
极限抗拉强度
丝绸
纳米晶
模数
纳米技术
凝聚态物理
结晶学
冶金
物理
量子
化学
量子力学
作者
Hao Zhang,Leitao Cao,Jian Li,Yifan Liu,Zhuochen Lv,Jing Ren,Zhengzhong Shao,Shengjie Ling
标识
DOI:10.1021/acs.chemmater.2c03536
摘要
Innovations in ionotronics have greatly facilitated the development of ultraflexible devices, displays, and machines. However, ionotronics often suffer from an inherent trade-off between stretchability and elasticity due to their viscous nature. Here, we overcome this limitation by incorporating dimension-and-content-confined nanocrystalline crosslinks into amorphous and molecularly entangled silk fibroin (SF) ionotronics. The welding-entanglement network exhibited a 34-fold increase in Young’s modulus, a 14-fold increase in tensile strength, and a 9-fold increase in toughness compared to the same SF material without the nanocrystal crosslinks. The welding-entanglement network also gained recoverable hysteretic energy dissipation with hysteresis as low as 22%. The stretchability and low hysteresis exhibited by these SF ionoelastomers far exceed those of previously reported ionotronics and bioelastomers. These mechanical merits, together with the inherent advantages of SF ionoelastomers, including their multiprocessability, sustainability, biocompatibility, and degradability, promote their applications in human–machine interfaces and bio-functional devices.
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