Preparation, characterization, and properties of polyacrylonitrile–silica gel anion exchange composite fibers

Khan, Asif Ali; Baig, Umair

doi:10.1002/pen.23442

Cited by 7 publications

(10 citation statements)

References 29 publications

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“…Poly(ethylene oxide) (PEO) shows a semicrystalline structure characterized by a 7/2 chain helix conformation and low melting temperature (66 C), low density (1.20 g/cm 3 ) and ability to solvate a wide variety of salts through interaction of its ether oxygens with cations [36,37]. Poly(acrylonitrile) (PAN) is also a semi-crystalline polymer and has numerous advantages provided by the relatively easy modification of its physico-chemical properties (hydrophilicity, porosity and mechanical strength) [38], being compatible with most salts [39]. Poly(methyl methacrylate) (PMMA) has been used in different applications such as medical and energy application and shows good mechanical strength, excellent optical properties (clarity, brilliance, transparency) and chemical resistance [40,41].…”

Section: Introductionmentioning

confidence: 99%

Polymer composites and blends for battery separators: State of the art, challenges and future trends

Nunes-Pereira

Costa

Lanceros‐Méndez

2015

Journal of Power Sources

241

145

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Section: Introductionmentioning

confidence: 99%

Polymer composites and blends for battery separators: State of the art, challenges and future trends

Nunes-Pereira

Costa

Lanceros‐Méndez

2015

Journal of Power Sources

241

145

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“…When the PAN was processed into fibers (Figure f), the peak at 2340 cm −1 (CN conjugation) displayed stronger intensity, probably due to the cyclization reaction between DMF and PAN . And the stretching nitrile (CN) group shifted to higher energy position at 2360 cm −1 (CN), ascribing to the interaction of amide nitrogen (DMF) and nitrile group (PAN) . The spectra of raw PMMA powder, PMMA fibers, PMMA/PAN porous thin films, core–shell hollow PMMA/PAN fibers, and PMMA/PAN porous fibers showed a weak peak around 999 cm −1 and two strong peaks at 1146 and 1726 cm −1 , corresponding to the vibrations of C–H, axial asymmetric bend of CCO and PMMA ester (CO) groups, respectively (Figure a–e) .…”

Section: Resultsmentioning

confidence: 96%

“…The peak at 2362 cm −1 (OCH 3 stretch) was observed in the PMMA powders, but disappeared in the PMMA fibers (Figure b), which may be caused by the severe synthesis condition (high voltage, 15.0 kV), similar to the synthesis procedure of the silica aerogels . Furthermore, the peaks (2362 cm −1 ) of the PAN/PMMA core–shell fibers and porous fibers could be assigned to the stretching nitrile (CN) group of PAN …”

Section: Resultsmentioning

confidence: 99%

“…[49][50][51][52] And the stretching nitrile (C N) group shifted to higher energy position at 2360 cm −1 ( C N), ascribing to the interaction of amide nitrogen (DMF) and nitrile group (PAN). [50][51][52][53][54] The spectra of raw PMMA powder, PMMA fibers, PMMA/PAN porous thin films, core-shell hollow PMMA/PAN fibers, and PMMA/PAN porous fibers showed a weak peak around 999 cm −1 and two strong peaks at 1146 and 1726 cm −1 , corresponding to the vibrations of C-H, axial asymmetric bend of C C O and PMMA ester ( C O) groups, respectively (Figure 4a-e). [55] The peaks at around 1195-1265 cm −1 were obtained due to the C O C stretching and deformation vibration.…”

Section: Morphology Studymentioning

confidence: 99%

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Comparatively Thermal and Crystalline Study of Poly(methyl‐methacrylate)/Polyacrylonitrile Hybrids: Core–Shell Hollow Fibers, Porous Fibers, and Thin Films

Huang

Cao

Huang

et al. 2016

Macro Materials & Eng

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The polyacrylonitrile/polymethyl-methacrylate (PMMA/PAN) porous fibers, core–shell hollow fibers, and porous thin films are prepared by coaxial electrospinning, single electrospinning, and spin-coating technologies, respectively. The different morphologies arising from different processes display great influences on their thermal and crystalline properties. The adding of PMMA causes porous structure due to the microphase-separation structure of immiscible PMMA and PAN phases. The lower weight loss, higher degradation temperature, and glass-transition temperatures of porous thin films than those of porous fibers and core–shell hollow fibers are obtained, evidencing that the polymer morphologies produced from the different process can efficiently influence their physical properties. The orthorhombic structure of PAN crystals are found in the PMMA/PAN porous thin films, but the rotational disorder PAN crystals due to intermolecular packing are observed in the PMMA/PAN porous fibers and core–shell hollow fibers, indicating that different processes cause different types of PAN crystals.

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“…Figure 5a-d shows Figure 5a shows the first stage weight loss at 100°C, due to the water evaporation in the mat. The second stage weight loss occurs at 280°C, due to the decomposition of the polymer chain (Khan and Baig 2013). Figure 5b shows the first weight loss at 100°C for PAN yarn waste/0.5 wt% GO composite mat, which may be attributed to water evaporation.…”

Section: Thermal Stabilitymentioning

confidence: 96%

An effective removal of methylene blue dye using polyacrylonitrile yarn waste/graphene oxide nanofibrous composite

Subramanian

Muthumanickkam

Imayathamizhan

2014

Int. J. Environ. Sci. Technol.

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An electrospun nanofibrous composite mat was prepared from polyacrylonitrile yarn waste and graphene oxide. The physical and chemical properties of the nanofibrous composites were characterized using attenuated total reflections Fourier transform infrared, scanning electron microscopy, X-ray diffractometer, and TGA studies. The mean fiber diameters of the pristine polyacrylonitrile yarn waste nanofiber, polyacrylonitrile yarn waste/0.5 wt% graphene oxide, polyacrylonitrile yarn waste/1.0 wt% graphene oxide, and polyacrylonitrile yarn waste/1.5 wt% graphene oxide nanofibrous composites were in the range of 41-50, 31-40, 31-40, and 31-40 nm, respectively. The mean pore sizes of the polyacrylonitrile yarn waste nanofiber, polyacrylonitrile yarn waste/0.5 wt% graphene oxide, polyacrylonitrile yarn waste/1.0 wt% graphene oxide, and polyacrylonitrile yarn waste/1.5 wt% graphene oxide nanofibrous composites were 0.5541, 0.4533, 0.4229, and 0.4168 lm, respectively. The maximum dye removal efficiency was attained in the polyacrylonitrile yarn waste/1.5 wt% graphene oxide composite at basic pH.

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Preparation, characterization, and properties of polyacrylonitrile–silica gel anion exchange composite fibers

Cited by 7 publications

References 29 publications

Polymer composites and blends for battery separators: State of the art, challenges and future trends

Polymer composites and blends for battery separators: State of the art, challenges and future trends

Comparatively Thermal and Crystalline Study of Poly(methyl‐methacrylate)/Polyacrylonitrile Hybrids: Core–Shell Hollow Fibers, Porous Fibers, and Thin Films

An effective removal of methylene blue dye using polyacrylonitrile yarn waste/graphene oxide nanofibrous composite

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