Degradation of regenerated cellulose filaments by hydrogen chloride under aqueous and non-aqueous conditions

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Degradation of regenerated cellulose filaments by hydrogen chloride under aqueous and non-aqueous conditions. / Ungerer, Bernhard; Sulaeva, Irina; Bodner, Sabine et al.
In: Carbohydrate polymer technologies and applications, Vol. 4.2022, No. December, 100238, 12.2022.

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Ungerer B, Sulaeva I, Bodner S, Potthast A, Keckes J, Müller U et al. Degradation of regenerated cellulose filaments by hydrogen chloride under aqueous and non-aqueous conditions. Carbohydrate polymer technologies and applications. 2022 Dec;4.2022(December):100238. Epub 2022 Aug 6. doi: 10.1016/j.carpta.2022.100238

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@article{be5a563a9d27498fb47aa647bea92eec,
title = "Degradation of regenerated cellulose filaments by hydrogen chloride under aqueous and non-aqueous conditions",
abstract = "Cellulose (rayon) filaments were exposed to various concentrations of hydrochloric acid under aqueous and non-aqueous conditions in order to study differences in degradation. Two sources of polymeric diphenylmethane diisocyanate (pMDI) were used as non-aqueous media. As a consequence of the production process, pMDI was found to contain residual hydrochloric acid. Filament yarns were immersed for either 7 h or 7 d and purified to obtain pure filaments for further analysis. Single-filament tensile tests and molar mass measurements confirmed a significant degradation of the filament structure under non-aqueous conditions. Samples with the same amount of hydrochloric acid immersed in water, however, were rarely affected. Complementary X-ray diffraction indicated that the removal of the amorphous cellulose resulted in an increase in the cellulose crystallinity, which was manifested by a decrease in the width of the diffraction peaks. With this remarkable difference between aqueous and non-aqueous treatments, a quantitative proof to a new aspect about the processability of regenerated cellulose was presented. Amongst other fields of technical applications, these findings will have to be considered in composite engineering dealing with cellulosic fibre reinforcements. An effective way to avoid acidic hydrolysis was presented based on calcium carbonate as matrix filler.",
keywords = "Acidic degradation, Cellulose, Crystallinity, Molar mass distribution, Viscose",
author = "Bernhard Ungerer and Irina Sulaeva and Sabine Bodner and Antje Potthast and Jozef Keckes and Ulrich M{\"u}ller and Stefan Veigel",
note = "Publisher Copyright: {\textcopyright} 2022",
year = "2022",
month = dec,
doi = "10.1016/j.carpta.2022.100238",
language = "English",
volume = "4.2022",
journal = "Carbohydrate polymer technologies and applications",
issn = "2666-8939",
publisher = "Elsevier",
number = "December",

}

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TY - JOUR

T1 - Degradation of regenerated cellulose filaments by hydrogen chloride under aqueous and non-aqueous conditions

AU - Ungerer, Bernhard

AU - Sulaeva, Irina

AU - Bodner, Sabine

AU - Potthast, Antje

AU - Keckes, Jozef

AU - Müller, Ulrich

AU - Veigel, Stefan

N1 - Publisher Copyright: © 2022

PY - 2022/12

Y1 - 2022/12

N2 - Cellulose (rayon) filaments were exposed to various concentrations of hydrochloric acid under aqueous and non-aqueous conditions in order to study differences in degradation. Two sources of polymeric diphenylmethane diisocyanate (pMDI) were used as non-aqueous media. As a consequence of the production process, pMDI was found to contain residual hydrochloric acid. Filament yarns were immersed for either 7 h or 7 d and purified to obtain pure filaments for further analysis. Single-filament tensile tests and molar mass measurements confirmed a significant degradation of the filament structure under non-aqueous conditions. Samples with the same amount of hydrochloric acid immersed in water, however, were rarely affected. Complementary X-ray diffraction indicated that the removal of the amorphous cellulose resulted in an increase in the cellulose crystallinity, which was manifested by a decrease in the width of the diffraction peaks. With this remarkable difference between aqueous and non-aqueous treatments, a quantitative proof to a new aspect about the processability of regenerated cellulose was presented. Amongst other fields of technical applications, these findings will have to be considered in composite engineering dealing with cellulosic fibre reinforcements. An effective way to avoid acidic hydrolysis was presented based on calcium carbonate as matrix filler.

AB - Cellulose (rayon) filaments were exposed to various concentrations of hydrochloric acid under aqueous and non-aqueous conditions in order to study differences in degradation. Two sources of polymeric diphenylmethane diisocyanate (pMDI) were used as non-aqueous media. As a consequence of the production process, pMDI was found to contain residual hydrochloric acid. Filament yarns were immersed for either 7 h or 7 d and purified to obtain pure filaments for further analysis. Single-filament tensile tests and molar mass measurements confirmed a significant degradation of the filament structure under non-aqueous conditions. Samples with the same amount of hydrochloric acid immersed in water, however, were rarely affected. Complementary X-ray diffraction indicated that the removal of the amorphous cellulose resulted in an increase in the cellulose crystallinity, which was manifested by a decrease in the width of the diffraction peaks. With this remarkable difference between aqueous and non-aqueous treatments, a quantitative proof to a new aspect about the processability of regenerated cellulose was presented. Amongst other fields of technical applications, these findings will have to be considered in composite engineering dealing with cellulosic fibre reinforcements. An effective way to avoid acidic hydrolysis was presented based on calcium carbonate as matrix filler.

KW - Acidic degradation

KW - Cellulose

KW - Crystallinity

KW - Molar mass distribution

KW - Viscose

UR - http://www.scopus.com/inward/record.url?scp=85135959082&partnerID=8YFLogxK

U2 - 10.1016/j.carpta.2022.100238

DO - 10.1016/j.carpta.2022.100238

M3 - Article

AN - SCOPUS:85135959082

VL - 4.2022

JO - Carbohydrate polymer technologies and applications

JF - Carbohydrate polymer technologies and applications

SN - 2666-8939

IS - December

M1 - 100238

ER -