Spectroscopic elucidation of structure-property relations in filaments melt-spun from amorphous polymers

Leal, A. Andrés; Best, James P.; Rentsch, Daniel; Michler, Johann; Hufenus, Rudolf

doi:10.1016/j.eurpolymj.2017.02.009

Cited by 9 publications

(4 citation statements)

References 48 publications

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“…A rich variety of spectral features is observed, the strongest of which lies in the interval 2800-2950 cm −1 and stems from the characteristic C-H stretching vibrations (ν CH ), common in hydrocarbons but also observed in Raman spectra of the same type of Zeonor films [42]. More importantly, a series of closely spaced or overlapping features is evidenced below 1500 cm −1 , attributed to rocking, twisting, and bending vibrations, the most characteristic being the CH 2 bending (δ CH2 ) and rocking (2ρ CH2 ) modes [43], which in our measurements peaked at 1446 cm −1 .…”

Section: µRaman Spectroscopymentioning

confidence: 82%

Fabrication and spectroscopic characterization of graphene transparent electrodes on flexible cyclo-olefin substrates for terahertz electro-optic applications

et al. 2020

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We demonstrate graphene on flexible, low-loss, cyclo-olefin polymer films as transparent electrodes for terahertz electro-optic devices and applications. Graphene was grown by chemical vapor deposition and transferred to cyclo-olefin polymer substrates by the thermal release tape method as layers on an approximate area of 4 cm 2 . The structural and electromagnetic properties of the graphene samples as well as their spatial variation were systematically mapped by means of µRaman, terahertz time-domain and mid-infrared spectroscopy. Thanks to the small thickness and very low intrinsic absorption of the employed substrates, both high transmittance and conductivity were recorded, demonstrating the suitability of the technique for the fabrication of a new class of transparent and flexible electrodes working in the terahertz spectrum.

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Section: µRaman Spectroscopymentioning

confidence: 82%

Fabrication and spectroscopic characterization of graphene transparent electrodes on flexible cyclo-olefin substrates for terahertz electro-optic applications

et al. 2020

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“…The morphology of solid-state polymers typically fluctuates continuously between ideal crystalline and fully amorphous states, where “amorphous” is widely used in polymer science to mean non-crystalline [ 62 , 63 ]. Polymers with irregular molecular structures cannot crystallize under any condition, so the only important morphological feature that can be changed through processing is molecular orientation [ 64 ].…”

Section: Raw Materials For Melt-spinningmentioning

confidence: 99%

Melt-Spun Fibers for Textile Applications

et al. 2020

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Textiles have a very long history, but they are far from becoming outdated. They gain new importance in technical applications, and man-made fibers are at the center of this ongoing innovation. The development of high-tech textiles relies on enhancements of fiber raw materials and processing techniques. Today, melt spinning of polymers is the most commonly used method for manufacturing commercial fibers, due to the simplicity of the production line, high spinning velocities, low production cost and environmental friendliness. Topics covered in this review are established and novel polymers, additives and processes used in melt spinning. In addition, fundamental questions regarding fiber morphologies, structure-property relationships, as well as flow and draw instabilities are addressed. Multicomponent melt-spinning, where several functionalities can be combined in one fiber, is also discussed. Finally, textile applications and melt-spun fiber specialties are presented, which emphasize how ongoing research efforts keep the high value of fibers and textiles alive.

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“…Unlike the crystallizable polymers described above, PSF- b -PEG represents a two-phase structure in which the majority PSF block is an amorphous polymer while the minority PEG block can crystallize. Thus, during the stretching process, the matrix formed from the amorphous but rigid PSF may have a significant impact on the crystallization of the flexible PEG block . Besides, the swelling behavior of the oriented molecular chains caused by stretching in selective solvents is also unclear.…”

Section: Introductionmentioning

confidence: 99%

“…Thus, during the stretching process, the matrix formed from the amorphous but rigid PSF may have a significant impact on the crystallization of the flexible PEG block. 28 Besides, the swelling behavior of the oriented molecular chains caused by stretching in selective solvents is also unclear. Thus, in this work, stretching is introduced to the melt-spun PSF-b-PEG hollow fibers followed by selective swelling in order to regulate the initial membrane dimensions as well as membrane thickness and consequently to improve the separation performance of the HFMs.…”

Section: Introductionmentioning

confidence: 99%

Selective Swelling of Stretched Block Copolymer Hollow Fibers for Upgraded Membrane Performance

Zhong

Qiu

Zhou

et al. 2022

ACS Appl. Polym. Mater.

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Block copolymers are showing great potential in the preparation of advanced membranes for precise separations, and there is a strong interest in the development of hollow-fiber membranes (HFMs) from block copolymers. Herein, we report polysulfone-block-poly(ethylene glycol) (PSF-b-PEG) HFMs with enhanced separation performance prepared by a convenient stretching strategy. Axial stretching is first applied to the meltspun PSF-b-PEG hollow fibers, efficiently reducing the wall thickness and outer diameter of the hollow fibers. The stretched hollow fibers are then subjected to selective swelling, thus producing HFMs with interconnected nanoporosity. We find that the degree of stretching significantly influences the diameter, length, and separation performance as well as the crystallization behavior of the hollow fibers before and after selective swelling. With a stretching percentage of 527%, the HFMs exhibit simultaneously enhanced water permeance and rejection because of thinned fiber walls and reduced pore sizes. This work reveals the important role of axial stretching in upgrading the performance of block copolymer HFMs and demonstrates that the selective swelling coupled with melt spinning is promising in the cleaner preparation of HFMs.

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Spectroscopic elucidation of structure-property relations in filaments melt-spun from amorphous polymers

Cited by 9 publications

References 48 publications

Fabrication and spectroscopic characterization of graphene transparent electrodes on flexible cyclo-olefin substrates for terahertz electro-optic applications

Fabrication and spectroscopic characterization of graphene transparent electrodes on flexible cyclo-olefin substrates for terahertz electro-optic applications

Melt-Spun Fibers for Textile Applications

Selective Swelling of Stretched Block Copolymer Hollow Fibers for Upgraded Membrane Performance

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