Abstract
The novel method, handspinning (HS), was invented by mimicking commonly observed methods in our daily lives. The use of HS allows us to fabricate carbon nanotube-reinforced nanofibers (CNT-reinforced nanofibers) by addressing three significant challenges: (i) the difficulty of forming nanofibers at high concentrations of CNTs, (ii) aggregation of the CNTs, and (iii) control of the orientation of the CNTs. The handspun nanofibers showed better physical properties than fibers fabricated by conventional methods, such as electrospinning. Handspun nanofibers retain a larger amount of CNTs than electrospun nanofibers, and the CNTs are easily aligned uniaxially. We attributed these improvements provided by the HS process to simple mechanical stretching force, which allows for orienting the nanofillers along with the force direction without agglomeration, leading to increased contact area between the CNTs and the polymer matrix, thereby providing enhanced interactions. HS is a simple and straightforward method as it does not require an electric field, and, hence, any kinds of polymers and solvents can be applicable. Furthermore, it is feasible to retain a large amount of various nanofillers in the fibers to enhance their physical and chemical properties. Therefore, HS provides an effective pathway to create new types of reinforced nanofibers with outstanding properties.
Highlights
The electrospinning (ES) technique is an effective and attractive method that has been investigated extensively during the last few decades to fabricate nanofibers from a polymer solution[1,2,3]
In our previous report[11], we found that the diameter and surface morphologies of handspun fiber depend on solvent systems and processing conditions to control simple mechanical force
The diameter of the nanofibers decreased when the concentration of Carbon nanotubes (CNTs) increased up to 0.5–1.0 wt%. This occurred because CNTs exhibit high conductivity, which results in the reduction of the electrostatic potential, typically making smaller-diameter fibers in the ES process
Summary
Concentrated Carbon Nanotubes with Controlled Orientation in received: 18 August 2016 accepted: 31 October 2016 Published: 23 November 2016. The use of HS allows us to fabricate carbon nanotube-reinforced nanofibers (CNT-reinforced nanofibers) by addressing three significant challenges: (i) the difficulty of forming nanofibers at high concentrations of CNTs, (ii) aggregation of the CNTs, and (iii) control of the orientation of the CNTs. The handspun nanofibers showed better physical properties than fibers fabricated by conventional methods, such as electrospinning. The simple mechanical stretching force in HS is more effective than the complicated, but weak, force induced by the electric field in ES to align the CNTs in the nanofiber. Given this rationale, for the proof of concept, poly(vinyl acetate) (PVAc) was chosen as the polymer matrix to test the potential of HS. The fibers showed more improved mechanical and thermal properties electrospun fibers, confirming the positive impacts of the HS method
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