AI Article Synopsis
- Conventional straight carbon nanotube fibers are rigid and limited in flexibility; creating spiral structures significantly improves their deformability and structural versatility.
- Researchers developed long threads of single-walled nanotubes twisted into 1.3 × 10^5 spiral loops per meter, which can be modified for different diameters and electrical conductivity.
- These spiral fibers exhibit unique properties like self-shrinking, enhanced resilience, and excellent fatigue resistance, making them promising for applications in temperature sensing, gas sensing, and innovative wearable electronics.
Article Abstract
Conventional straight fibers spun from carbon nanotubes have rather limited deformability; creating a spiral structure holds the promise to break this shape restriction and enhance structural flexibility. Here, we report up to one meter-length threads containing purely single-walled nanotubes twisted into spiral loops (about 1.3 × 10(5) loops per meter) with tunable fiber diameters and electrical conductivity. Because of significant increase of the loop number and long-range homogeneity, the fibers display many unique properties (e.g., self-shrinking and forming extremely entangled structure, fast stretching with great resilience, large-degree axial and lateral deflection, and excellent fatigue resistance) that are difficult to achieve in straight yarns or short helical segments. They also have potential applications as macroscopic fiber-shaped temperature sensors and deformable gas sensors. Our long spiral fibers may be configured into versatile structures such as nanotextiles for developing wearable electronics and multifunctional fabrics.
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| http://dx.doi.org/10.1021/acs.nanolett.5b04773 | DOI Listing |
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