材料科学
丝绸
碳纳米管
复合材料
复合数
极限抗拉强度
丝素
热导率
电阻率和电导率
玻璃纤维
热的
电导率
导电体
碳纤维
比强度
环氧树脂
作者
Yuito Horita,Mayumi Mizutani,Aghnia Dinan Maulani Heriyanto,Takeshi Watanabe,Masakazu Nakamura,Hironari Kamikubo,Shinji Koh
标识
DOI:10.1016/j.matdes.2025.115007
摘要
• SWCNT/silk composites were prepared from silk at different degumming ratios. • Degumming ratio affected properties of the composite fibers. • Degumming enhanced SWCNT adhesion, improving electrical & thermal conductivities. • Further degumming led to fibroin loss, reducing tensile strength and elongation. Electronic textiles are emerging as key materials for next-generation flexible wearable devices. Silk is an attractive candidate owing to its high durability, light weight, and flexibility, while single-walled carbon nanotubes (SWCNTs) provide excellent electrical and thermal conductivity along with chemical stability. However, achieving high conductivity in CNT/silk composite fibers without compromising the intrinsic strength of silk remains a significant challenge. In this study, we fabricated SWCNT/silk composite fibers using a polydopamine (PDA)-assisted dip-and-dry method and systematically optimized the silk degumming ratio to obtain fibers with excellent electrical and thermal conductivity. At an optimal silk degumming ratio of 25 wt%, the PDA-coated SWCNT/silk composite fibers exhibited an excellent electrical conductivity of 315 S/cm, a high tensile strength of 150 MPa, and a thermal conductivity of 6.3 W/mK. By simultaneously achieving high electrical, mechanical, and thermal performance, the proposed strategy overcomes key limitations of existing CNT/silk composites and highlights the potential of these fibers as promising materials for next-generation flexible electronic textiles.
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