材料科学
气凝胶
石墨烯
热导率
纳米技术
电子设备和系统的热管理
氧化物
压阻效应
热电效应
织物
多孔性
复合材料
热的
可穿戴技术
智能材料
保温
纳米材料
伪装
数码产品
热能
柔性电子器件
弹性(材料科学)
作者
Qianqian Zhang,Qianqian Zhang,Lin Qiu,P. He,Ningqi Shao,Junhong Liu,Jiaqi Dong,Xin Wang,Yusheng Liang,Hengzhong Fan,Yongsheng Zhang,Qiangqiang Zhang,Qiangqiang Zhang
摘要
ABSTRACT Fiber‐based textiles capable of responding to external stimuli are crucial for flexible smart sensors and thermal management, yet they often lack the diverse functionalities required to simultaneously perceive electro‐thermo‐mechanical signals. In this study, polar‐bear‐hair bionic hollow graphene aerogel fibers (GAFs) were controllably fabricated via a scalable coaxial‐extrusion‐spinning process combined with a core‐component‐sacrificial method. Under promotion of shear stress in the outer channel, graphene oxide (GO) nanoplates self‐assemble into a hierarchically porous arch‐like microstructure. Precise regulation of the interfacial status and functional groups on reduced GO endow GAFs and the resulting smart textiles with tunable mechanical, electrical, and thermal properties. The low energy barrier and intense phonon scattering within the multiscale porous network result in the largest electrical conductivity (1457.09 S/m), record‐low thermal conductivity (1.28 mW/(m·K)) and remarkable elastic recovery (90% strain recovery) rather than those of most reported lightweight architectures. The flexible GAFs‐based textiles demonstrate multifunctional capabilities as sensitive wearable sensors based on either piezoresistive or thermoelectric effect, thermal barriers, and infrared stealth skins. This study provides a novel pathway for functional textiles of graphene aerogels in intelligent perception, self‐powered systems, fire alarming sensor, thermal management, and camouflage protection for both civilian and military applications.
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