材料科学
纺纱
编织
碳纳米管
复合材料
纱线
微观结构
织物
弯曲
变形(气象学)
扭转
纳米管
纳米技术
几何学
数学
作者
Huan Ma,Xiaoxiao Wei,Junling Liu,Wei Chen,Ruijie Wang,Fujun Xu
标识
DOI:10.1021/acsanm.4c06088
摘要
Carbon nanotube (CNT) yarns have attracted tremendous interest due to their huge potential in building advanced textiles; nevertheless, their thin diameter had hindered widespread adoption. To track the issues, in this article, a CNT film (a thickness of 17.75 μm) with entangled CNT bundles was twisted into a continuous CNT yarn with ultrathick diameter through a one-step twist-spinning procedure. The morphological transformation from a CNT film to a CNT yarn, the relationship between critical twist-spinning parameters, and the mechanical/electrical performances of the CNT yarns were investigated. The results showed that the twist-spinning procedure facilitated a shrinking effect, thereby promoting the uniform diameter and dense internal microstructure. Especially, Y-900 (a CNT yarn with a twist degree of 900 turns per meter) demonstrated an ultrathick and uniform diameter of 191.7 μm; moreover, its microstructure was densified. The superiority could effectively promote high-interface interactions and more conductive pathways between CNT bundles. Thus, the strength and conductivity of Y-900 are achieved to be 134.15 MPa and 602.12 S/cm, respectively. In addition, Y-900 demonstrated excellent stability when suffering cyclic bending deformation and friction deformation. Based on the above advantages, Y-900 was used for weaving fabric and further electrothermal textile application. This work provided insights into further multifunctional applications for the CNT yarns as textile materials.
科研通智能强力驱动
Strongly Powered by AbleSci AI