Fabrication of high strength PVA/SWCNT composite fibers by gel spinning

Xu, Xuezhu; Uddin, Ahmed Jalal; Aoki, Katsumi; Gotoh, Yasuo; Saito, Tetsuya; Yumura, Motoo

doi:10.1016/j.carbon.2010.02.004

Cited by 87 publications

(80 citation statements)

References 30 publications

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“…As shown in Fig. 6B, the intensities of D and G 416 peaks remain relatively constant for all the fibers and their I D / 417 I G ratios are all close to 0.85, indicating similar structural per-418 fection of graphitic carbons [98]. Peak shifts on both D and G 419 peaks can be observed for the fibers containing Fe or Pd nano-420 particles, which is presumably caused by electron doping or 421 mechanical strain effects of the nanoparticles [99].…”

mentioning

confidence: 69%

Lignin-based carbon fibers: Carbon nanotube decoration and superior thermal stability

Zhou

Jiang

et al. 2014

Carbon

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confidence: 69%

Lignin-based carbon fibers: Carbon nanotube decoration and superior thermal stability

Zhou

Jiang

et al. 2014

Carbon

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“…13 In particular, wet-spinning is a relatively simple process to produce continuous polymer microfibers by submerging the spinneret in a coagulation bath that causes the fiber to solidify. 13,14 Among the popular conjugated polymers, polypyrrole (PPy), polyaniline (PANI) and poly(3,4-ethylenedioxythiophene)/poly(styrenesulfonate)(PEDOT/PSS) have been successfully spun into microfibers by the wet-spinning process. 8,9,11,15 PEDOT/PSS has been found to have the best spinnability and its preparation technique can be scaled up to an industrial process.…”

Section: Introductionmentioning

confidence: 99%

Semi-metallic, strong and stretchable wet-spun conjugated polymer microfibers

et al. 2015

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A dramatic improvement in electrical conductivity is necessary to make conductive polymer fibers viable candidates in applications such as flexible electrodes, conductive textiles, and fast-response sensors and actuators. In this study, high-performance poly(3,4-ethylenedioxythiophene)/poly(styrenesulfonate) (PEDOT/PSS) conjugated polymer microfibers were fabricated via wet-spinning followed by hot-drawing. Due to the combined effects of the vertical hot-drawing process and doping/de-doping the microfibers with ethylene glycol (EG), we achieved a record electrical conductivity of 2804 S · cm −1 . This is, to the best of our knowledge, a six-fold improvement over the best previously reported value for PEDOT/PSS fibers (467 S · cm −1 ) and a two-fold improvement over the best values for conductive polymer films treated by EG de-doping (1418 S · cm −1 ). Moreover, we found that these highly conductive fibers experience a semiconductor-metal transition at 313 K. They also have superior mechanical properties with a Young's modulus up to 8.3 GPa, a tensile strength reaching 409.8 MPa and a large elongation before failure (21%). The most conductive fiber also demonstrates an extraordinary electrical performance during stretching/unstreching: the conductivity increased by 25% before the fiber rupture point with a maximum strain up to 21%. Simple fabrication of the semimetallic, strong and stretchable wet-spun PEDOT/PSS microfibers described here could make them available for conductive smart electronics.

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“…So far a popular method to fabricate CNT/polymer hybrids is through the technique of wet spinning. [23, 24, 28–34] Wet spinning has been utilized in producing CNT/polymer composite fibers for the last 10 years. [21, 23, 30] Despite its inherent advantage, the ability to scale up the production of CNT fibers, specifically those intended for biomedical applications, incurrs some drawbacks.…”

Section: Introductionmentioning

confidence: 99%

Biohybrid Carbon Nanotube/Agarose Fibers for Neural Tissue Engineering

Lewitus

Landers

Branch

et al. 2011

Adv Funct Materials

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We report a novel approach for producing carbon nanotube fibers (CNF) composed with the polysaccharide agarose. Current attempts to make CNF’s require the use of a polymer or precipitating agent in the coagulating bath that may have negative effects in biomedical applications. We show that by taking advantage of the gelation properties of agarose one can substitute the bath with distilled water or ethanol and hence reduce the complexity associated with alternating the bath components or the use of organic solvents. We also demonstrate that these CNF can be chemically functionalized to express biological moieties through available free hydroxyl groups in agarose. We corroborate that agarose CNF are not only conductive and nontoxic, but their functionalization can facilitate cell attachment and response both in vitro and in vivo. Our findings suggest that agarose/CNT hybrid materials are excellent candidates for applications involving neural tissue engineering and biointerfacing with the nervous system.

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Fabrication of high strength PVA/SWCNT composite fibers by gel spinning

Cited by 87 publications

References 30 publications

Lignin-based carbon fibers: Carbon nanotube decoration and superior thermal stability

Lignin-based carbon fibers: Carbon nanotube decoration and superior thermal stability

Semi-metallic, strong and stretchable wet-spun conjugated polymer microfibers

Biohybrid Carbon Nanotube/Agarose Fibers for Neural Tissue Engineering

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