Rheo-NMR study of water-based cellulose liquid crystal system at high shear rates

Rheo-NMR study of water-based cellulose liquid crystal system at high shear rates

Since long ago cellulosic lyotropic liquid crystals were thought as potential materials to produce fibers competitive with spidersilk or Kevlar, yet the processing of high modulus materials from cellulose-based precursors was hampered by their complex rheological behavior. In this work, by using the...

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Veröffentlicht in:Polymer (Guilford) 2015-05, Vol.65, p.18-25
Hauptverfasser: Echeverria, Coro, Almeida, Pedro L., Feio, Gabriel, Figueirinhas, João L., Rey, Alejandro D., Godinho, Maria H.
Format: Artikel
Sprache:eng
Schlagworte:
Alignment
Cellulose
Cellulose fibers
Helices
Liquid crystal
Liquid crystals
Nematic
Rheo-NMR
Rheological properties
Shear
Shear rate
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container_end_page 25
container_issue
container_start_page 18
container_title Polymer (Guilford)
container_volume 65
creator Echeverria, Coro
Almeida, Pedro L.
Feio, Gabriel
Figueirinhas, João L.
Rey, Alejandro D.
Godinho, Maria H.
description Since long ago cellulosic lyotropic liquid crystals were thought as potential materials to produce fibers competitive with spidersilk or Kevlar, yet the processing of high modulus materials from cellulose-based precursors was hampered by their complex rheological behavior. In this work, by using the Rheo-NMR technique, which combines deuterium NMR with rheology, we investigate the high shear rate regimes that may be of interest to the industrial processing of these materials. Whereas the low shear rate regimes were already investigated by this technique in different works [1–4], the high shear rates range is still lacking a detailed study. This work focuses on the orientational order in the system both under shear and subsequent relaxation process arising after shear cessation through the analysis of deuterium spectra from the deuterated solvent water. At the analyzed shear rates the cholesteric order is suppressed and a flow-aligned nematic is observed which for the higher shear rates develops after certain time periodic perturbations that transiently annihilate the order in the system. During relaxation the flow aligned nematic starts losing order due to the onset of the cholesteric helices leading to a period of very low order where cholesteric helices with different orientations are forming from the aligned nematic, followed in the final stage by an increase in order at long relaxation times corresponding to the development of aligned cholesteric domains. This study sheds light on the complex rheological behavior of chiral nematic cellulose-based systems and opens ways to improve its processing. [Display omitted] •We investigate by Rheo-NMR the behavior of LC-HPC at high shear rates.•Two order states separated by a disordered one are identified.•The relaxation behavior translates the viscoelastic and LC features of the material.•A critical shear rate is identified where maximum quadrupolar splitting is achieved.•The spectral shape's simulation was analyzed through the use of a simple model.
doi_str_mv 10.1016/j.polymer.2015.03.050
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subjects Alignment
Cellulose
Cellulose fibers
Helices
Liquid crystal
Liquid crystals
Nematic
Rheo-NMR
Rheological properties
Shear
Shear rate
title Rheo-NMR study of water-based cellulose liquid crystal system at high shear rates
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