Carbon fiber from natural biopolymer Bombyx mori silk fibroin with iodine treatment

Khan, Md. Majibur Rahman; Gotoh, Yasuo; Morikawa, Hideaki; Miura, Mikihiko; Fujimori, Yoshie; Nagura, Masanobu

doi:10.1016/j.carbon.2006.12.015

Cited by 54 publications

(29 citation statements)

References 19 publications

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“…Figure 1 shows Raman spectrum of pristine SWCNTs. The bands were observed at 1341 cm -1 (D band) and 1592 cm -1 (G band), corresponding to amorphous carbon impurities and carbon nanotubes, respectively [17]. The band intensity at 1341 cm -1 was extremely low, while the G-band had much higher intensity.…”

Section: Resultsmentioning

confidence: 97%

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

Uddin

Aoki

et al. 2010

Carbon

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High-strength composite fibers were prepared from polyvinyl alcohol (PVA) (Degree of polymerization: 1500) reinforced by single-walled carbon nanotubes (SWCNTs) containing few defects. The SWCNTs were dispersed in a 10 wt.% PVA/dimethylsulfoxide solution using a mechanical homogenizer that reduced the size of SWCNT aggregations to smaller bundles. The macroscopically homogeneous dispersion was extruded into cold methanol to form fibers by gel spinning followed by a hot-drawing. The tensile strength of the well-oriented composite fibers with 0.3 wt.% SWCNTs was 2.2 GPa which is extremely high value among PVA composite fibers ever reported using a commercial grade PVA. The strength of neat PVA fibers prepared by the same procedure was 1.7 GPa. Structural analysis showed that the PVA component in the composite fibers possessed almost the same structure as that of neat PVA fibers.Hence a small amount of SWCNTs straightforward enhanced by 0.5 GPa the tensile strength of PVA fibers. The results of mechanical properties and Raman spectra for the SWCNT composites suggest the relatively good interfacial adhesion of the nanotubes and PVA that improves the load transfer from the polymer matrix to the reinforcing phase.-3 -

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Section: Resultsmentioning

confidence: 97%

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

Uddin

Aoki

et al. 2010

Carbon

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“…19,20 The use of iodine treatment to increase the carbon yield has also been extended to biobased precursors, such as silk broin. 21 In other work, sulphuric acid treatment of cellulosic bre has been shown to increase the carbon yield by 300%.…”

Section: 18mentioning

confidence: 99%

Thermal, chemical and morphological properties of carbon fibres derived from chemically pre-treated wool fibres

2015

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In this work, the feasibility of using wool fibre as a carbon fibre precursor was explored as well as whether chemical treatments to wool fibre can increase the carbon fibre yield and properties of the produced carbon fibres. Wool fibres were treated with a range of chemicals including lignin, tannic acid, polystyrene sulphonate, and chlorine in conjunction with a polyamide resin. The treated fibres were stabilised in air at 160 C followed by pyrolysis at 800 C under a nitrogen atmosphere. The resulting carbon fibres were characterised in terms of carbon yield, tensile strength, surface roughness, porosity, crystal structure and surface hydrophobicity. The carbon fibre yield was 16.7% for the untreated while the lignin pre-treatment increased the carbon yield up to 25.8%. Generally the surface of the carbon fibre made from both untreated and treated fibre exhibited high hydrophilicity except the lignin and chlorine/polyamide resintreated fibre which showed hydrophobicity. Although the tensile strength achieved for the various produced carbon fibre was poor compared to a commercially available pitch-based carbon fibre, the developed carbon fibre still can be utilised in thermoplastic composite manufacturing.

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“…Under identical conditions and in the same line of investigation as in [116], Kahn et al [118] studied the carbon formation from Antheraea pernyi silk fibroin fiber. The composition of the latter silk is different from that of B. mori silk, having predominantly alanine (Ala), aspartic acid (Asp), and arginine (Arg) amino acid residues.…”

Section: Iodine-proteinic Fiber Complexesmentioning

confidence: 99%

“…Shao and his coworkers [115] treated a degummed and UV/ozone irradiated B. mori silk fiber with saturated iodine ethanolic solution in the dark at 22°C for 24 h. The content of iodine was about 5% in the bulk iodinated silk and 0.9% on the surface. Khan et al [116] reported a process of making carbon fiber from B. mori silk fibroin after iodine treatment. The silk fibroin was exposed to iodine vapors at 100°C for varying periods of time, after which the fiber color turned to dark brown.…”

Section: Iodine-proteinic Fiber Complexesmentioning

confidence: 99%

Molecular iodine/polymer complexes

Moulay

2013

Journal of Polymer Engineering

154

121

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A unique feature of molecular iodine by far, is its ability to bind to polymeric materials. A plethora of natural and synthetic polymers develop complexes when treated with molecular iodine, or with a mixture of mole cular iodine and potassium iodide. Many unexpected findings have been encountered upon complexation of iodine and the polymer skeleton, including the color formation, the polymer morphology changes, the compl exation sites or regions, the biological activity, and the electrical conductivity enhancement of the complexes, with poly iodides (I n¯) , mainly I 3¯ and I 5¯, as the actual binding species. Natural polymers that afford such complexes with iodine species are starch (amylose and amylopectin), chitosan, glycogen, silk, wool, albumin, cellulose, xylan, and natural rubber; iodinestarch being the oldest iodinenatural polymer complex. By contrast, numerous synthetic polymers are prone to make com plexes, including poly(vinyl alcohol) (PVA), poly(vinyl pyrrolidone) (PVP), nylons, poly(Schiff base)s, poly aniline, unsaturated polyhydrocarbons (carbon nano tubes, fullerenes C 60 /C 70 , polyacetylene; iodinePVA being the oldest iodinesynthetic polymer complex.

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Carbon fiber from natural biopolymer Bombyx mori silk fibroin with iodine treatment

Cited by 54 publications

References 19 publications

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

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

Thermal, chemical and morphological properties of carbon fibres derived from chemically pre-treated wool fibres

Molecular iodine/polymer complexes

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