摩擦电效应
纺纱
同轴
材料科学
纳米发生器
复合数
复合材料
电压
可穿戴技术
可穿戴计算机
纤维
耐久性
导电体
电容器
纳米技术
可扩展性
超级电容器
计算机科学
镊子
智能材料
作者
Zhihao Peng,Ying Chen,Xulong Zheng,Tianyu Wang,Fujun Han,Kairui Wang,Yiyan Gao,Ya Cheng,Guanghui Gao
标识
DOI:10.1016/j.cej.2025.169304
摘要
The development of wearable self-powered systems faces the daunting challenge of balancing high energy output, mechanical durability, and seamless integration with textiles. In this work, we presented an innovative core-shell composite fiber triboelectric nanogenerator (CSF-TENG) fabricated by a scalable coaxial wet-spinning strategy that synergistically integrated energy harvesting, environmental adaptation, and smart sensing. This fiber consisted of a graphene-bridged thermoplastic polyurethane (TPU) conductive core for efficient charge transfer and TiO₂-doped TPU triboelectric shell for simultaneously enhanced surface charge density and washability. CSF-TENG provided excellent output (open-circuit voltage of 130 V, short-circuit voltage of 3.9 μA, power density of 128.9 mW/m 2 ) meanwhile maintained breathability and elongation (>500 % strain). Woven into a fabric (WCSF-TENG), the composite material system functions as the self-powered human motion sensor, capturing subtle physiological signals, such as respiration and joint movements. Furthermore, WCSF-TENG also was used as an encrypted emergency communication platform for voice visualization and silent distress alerting via a wristband interface, on the basis of Morse code. This work demonstrated a viable composite material strategy which could be scalable to the next-generation smart textiles, effectively addressing the persistent trade-offs among performance, durability, and large-scale manufacturability in wearable electronics.
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