Regenerated and rotation-induced cellulose-wrapped oriented CNT fibers for wearable multifunctional sensors

Recently, wearable multifunctional fibers have attracted widespread attention due to their applications in wearable smart textiles. However, stable application, large-scale production and more functions are still the greatest challenges for functional fiber devices. In this study, wearable multi-fun...

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Bibliographic Details
Published in:Nanoscale 2020-08, Vol.12 (3), p.1635-16314
Main Authors: Jing, Changfei, Liu, Weihua, Hao, Huali, Wang, Huagao, Meng, Fanbin, Lau, Denvid
Format: Article
Language:English
Subjects:
Bonding strength
Carbon nanotubes
Cellulose
Cellulose fibers
Coagulation
Electric contacts
Functionals
Hydrogen bonding
Molecular dynamics
Ohmic dissipation
Resistance heating
Rotation
Sensors
Sheaths
Smart materials
Textiles
Wearable technology
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Summary:Recently, wearable multifunctional fibers have attracted widespread attention due to their applications in wearable smart textiles. However, stable application, large-scale production and more functions are still the greatest challenges for functional fiber devices. In this study, wearable multi-functional coaxial fibers with oriented carbon nanotubes (CNTs) were achieved for the first time coaxial wet-spinning with rotating coagulation bath. Specifically, the cellulose solution can be regenerated in the coagulation bath and the CNTs dispersion will be oriented under the rotating force. The synergy between hydrogen bonding and van der Waals interaction enhance the mechanical strength of coaxial fibers. Especially, CNTs can prevent the rotation of the cellulose chain and the bending of the glycosidic twist angle at the atomic scale as indicated by molecular dynamics (MD) simulations. When the fibers are strained, the cellulose sheath will drive the movement of CNTs, causing changes involving the effective contact area and number of conductive paths. Therefore, the high electrical resistance response change enables the as-obtained coaxial fibers to exhibit a great potential in wearable strain sensors. Furthermore, coaxial fibers can be made into electric heaters based on the Joule heating principle. The heating temperature reaches more than 160 °C within 6 s at 10 V, which is of a great value for large area flexible heaters. Besides, the coaxial fibers can further be used as temperature-sensitive devices to accurately perceive the external temperature. Therefore, the scalable synthesis of multifunctional coaxial fibers is significantly expected to provide a platform for the large-scale production of multifunctional wearable intelligent textiles. Recently, wearable multifunctional fibers have attracted widespread attention due to their applications in wearable smart textiles.
ISSN:2040-3364
2040-3372
DOI:10.1039/d0nr03684f