Yielding and flow of cellulose microfibril dispersions in the presence of a charged polymer

Daan W. De Kort; Sandra J. Veen; Henk Van As; Daniel Bonn; Krassimir P. Velikov; John P.M. Van Duynhoven

doi:10.1039/c5sm02869h

Yielding and flow of cellulose microfibril dispersions in the presence of a charged polymer

Daan W. De Kort, Sandra J. Veen, Henk Van As, Daniel Bonn, Krassimir P. Velikov, John P.M. Van Duynhoven^*

^*Corresponding author for this work

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Abstract

The shear flow of microfibrillated cellulose dispersions is still not wholly understood as a consequence of their multi-length-scale heterogeneity. We added carboxymethyl cellulose, a charged polymer, that makes cellulose microfibril dispersions more homogeneous at the submicron and macro scales. We then compared the yielding and flow behavior of these dispersions to that of typical thixotropic yield-stress fluids. Despite the apparent homogeneity of the dispersions, their flow velocity profiles in cone-plate geometry, as measured by rheo-MRI velocimetry, differ strongly from those observed for typical thixotropic model systems: the viscosity across the gap is not uniform, despite a flat stress field across the gap. We describe these velocity profiles with a nonlocal model, and attribute the non-locality to persistent micron-scale structural heterogeneity.

Original language	English
Pages (from-to)	4739-4744
Number of pages	6
Journal	Soft Matter
Volume	12
Issue number	21
DOIs	https://doi.org/10.1039/c5sm02869h
Publication status	Published - 2016

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© 2016 The Royal Society of Chemistry.

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c5sm02869hFinal published version, 1.84 MBLicence: Taverne

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title = "Yielding and flow of cellulose microfibril dispersions in the presence of a charged polymer",

abstract = "The shear flow of microfibrillated cellulose dispersions is still not wholly understood as a consequence of their multi-length-scale heterogeneity. We added carboxymethyl cellulose, a charged polymer, that makes cellulose microfibril dispersions more homogeneous at the submicron and macro scales. We then compared the yielding and flow behavior of these dispersions to that of typical thixotropic yield-stress fluids. Despite the apparent homogeneity of the dispersions, their flow velocity profiles in cone-plate geometry, as measured by rheo-MRI velocimetry, differ strongly from those observed for typical thixotropic model systems: the viscosity across the gap is not uniform, despite a flat stress field across the gap. We describe these velocity profiles with a nonlocal model, and attribute the non-locality to persistent micron-scale structural heterogeneity.",

author = "{De Kort}, {Daan W.} and Veen, {Sandra J.} and {Van As}, Henk and Daniel Bonn and Velikov, {Krassimir P.} and {Van Duynhoven}, {John P.M.}",

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T1 - Yielding and flow of cellulose microfibril dispersions in the presence of a charged polymer

AU - De Kort, Daan W.

AU - Veen, Sandra J.

AU - Van As, Henk

AU - Bonn, Daniel

AU - Velikov, Krassimir P.

AU - Van Duynhoven, John P.M.

PY - 2016

Y1 - 2016

N2 - The shear flow of microfibrillated cellulose dispersions is still not wholly understood as a consequence of their multi-length-scale heterogeneity. We added carboxymethyl cellulose, a charged polymer, that makes cellulose microfibril dispersions more homogeneous at the submicron and macro scales. We then compared the yielding and flow behavior of these dispersions to that of typical thixotropic yield-stress fluids. Despite the apparent homogeneity of the dispersions, their flow velocity profiles in cone-plate geometry, as measured by rheo-MRI velocimetry, differ strongly from those observed for typical thixotropic model systems: the viscosity across the gap is not uniform, despite a flat stress field across the gap. We describe these velocity profiles with a nonlocal model, and attribute the non-locality to persistent micron-scale structural heterogeneity.

AB - The shear flow of microfibrillated cellulose dispersions is still not wholly understood as a consequence of their multi-length-scale heterogeneity. We added carboxymethyl cellulose, a charged polymer, that makes cellulose microfibril dispersions more homogeneous at the submicron and macro scales. We then compared the yielding and flow behavior of these dispersions to that of typical thixotropic yield-stress fluids. Despite the apparent homogeneity of the dispersions, their flow velocity profiles in cone-plate geometry, as measured by rheo-MRI velocimetry, differ strongly from those observed for typical thixotropic model systems: the viscosity across the gap is not uniform, despite a flat stress field across the gap. We describe these velocity profiles with a nonlocal model, and attribute the non-locality to persistent micron-scale structural heterogeneity.

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Yielding and flow of cellulose microfibril dispersions in the presence of a charged polymer

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