Preparation of Lyocell Fibers from Solutions of Miscanthus Cellulose

Both annual (cotton, flax, hemp, etc.) and perennial (trees and grasses) plants can serve as a source of cellulose for fiber production. In recent years, the perennial herbaceous plant miscanthus has attracted particular interest as a popular industrial plant with enormous potential. This industrial...

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Veröffentlicht in:	Polymers 2024-10, Vol.16 (20), p.2915
Hauptverfasser:	Makarov, Igor S, Budaeva, Vera V, Gismatulina, Yulia A, Kashcheyeva, Ekaterina I, Zolotukhin, Vladimir N, Gorbatova, Polina A, Sakovich, Gennady V, Vinogradov, Markel I, Palchikova, Ekaterina E, Levin, Ivan S, Azanov, Mikhail V
Format:	Artikel
Sprache:	eng
Schlagworte:	Atmospheric pressure Caustic soda Cellulose Cellulose fibers Cotton Flax Hemp Industrial plants Infrared spectroscopy Lignin Methods Polymerization Raw materials Solvents Spectrum analysis Structural analysis Thermodynamic properties
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creator	Makarov, Igor S Budaeva, Vera V Gismatulina, Yulia A Kashcheyeva, Ekaterina I Zolotukhin, Vladimir N Gorbatova, Polina A Sakovich, Gennady V Vinogradov, Markel I Palchikova, Ekaterina E Levin, Ivan S Azanov, Mikhail V
description	Both annual (cotton, flax, hemp, etc.) and perennial (trees and grasses) plants can serve as a source of cellulose for fiber production. In recent years, the perennial herbaceous plant miscanthus has attracted particular interest as a popular industrial plant with enormous potential. This industrial crop, which contains up to 57% cellulose, serves as a raw material in the chemical and biotechnology sectors. This study proposes for the first time the utilization of miscanthus, namely Miscanthus Giganteus "KAMIS", to generate spinning solutions in N-methylmorpholine-N-oxide. Miscanthus cellulose's properties were identified using standard methods for determining the constituent composition, including also IR and atomic emission spectroscopy. The dry-jet wet method was used to make fibers from cellulose solutions with an appropriate viscosity/elasticity ratio. The structural characteristics of the fibers were studied using IR and scanning electron microscopy, as well as via X-ray structural analysis. The mechanical and thermal properties of the novel type of hydrated cellulose fibers demonstrated the possibility of producing high-quality fibers from miscanthus.
doi_str_mv	10.3390/polym16202915
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subjects	Atmospheric pressure Caustic soda Cellulose Cellulose fibers Cotton Flax Hemp Industrial plants Infrared spectroscopy Lignin Methods Polymerization Raw materials Solvents Spectrum analysis Structural analysis Thermodynamic properties
title	Preparation of Lyocell Fibers from Solutions of Miscanthus Cellulose
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