H. Van Damme scite author profile

Relations between thermodynamics, structural, and mechanical properties of Laponite suspensions were recently discussed in the literature. One important issue concerning the liquid/gel transition of the Laponite suspensions is to understand why a mechanical gel appears concomitantly with what appears as an incomplete nematic transition. To get some insight, we first give a more extended characterization of the viscoelastic properties of these suspensions near the liquid/gel transition. For this purpose, stress relaxation experiments are compared to direct determinations of the viscoelastic modulus in the frequency domain. This permits the following of viscoelastic properties, in the linear regime, on a very extended scale, from 10-5 to 102 rad/s. The data show that the relaxation mechanisms are very slow and are compatible with the presence of a large scale structural organization compared to the elementary particle size. The elastic modulus follows the power law: G‘ = A(C − C 0)α. Only the concentration threshold varies with the ionic strength. In a second part, we compare, on the same system, how the osmotic pressure and the birefringent properties are correlated. As already shown by Gabriel et al., three optical domains can be defined, an isotropic liquid, an isotropic gel, and a birefringence gel, where numerous threadlike defects highly reminiscent of nematic texture are observed. An interesting new result is seen, a line that separates the isotropic and the birefringent gel coincides with the line where the plateau of the osmotic pressure ends up. Recalling that the osmotic plateau starts just at the liquid/solid transition, we propose a more complete phase diagram exhibiting a pseudobiphasic region with no macroscopic phase separation.

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Dilatant Flow of Concentrated Suspensions of Rough Particles

Lootens

et al. 2005

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The flow anisotropy of a concentrated colloidal suspension at the jamming transition is studied. It is shown that the use of rough spherical particles reduces the hydrodynamic lubrication forces between adjacent colloids and makes possible the study of the stress tensor anisotropy. At low shear rates, the suspension exerts an attractive force between two opposite surfaces, whereas at higher shear rates it becomes dilatant. Direct confocal microscopy observation of the particles organization reveal that crystallites form at high shear rate.

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Fluorescence decay study of the adsorption of nonionic surfactants at the solid-liquid interface. 2. Influence of polar chain length

Levitz¹,

Damme²

1986

J. Phys. Chem.

178

158

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Fluorescence decay study of the adsorption of nonionic surfactants at the solid-liquid interface. 1. Structure of the adsorption layer on a hydrophilic solid

Levitz¹,

Damme²,

Keravis³

1984

J. Phys. Chem.

210

140

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H. Van Damme

On Viscoelastic, Birefringent, and Swelling Properties of Laponite Clay Suspensions: Revisited Phase Diagram

Dilatant Flow of Concentrated Suspensions of Rough Particles

Fluorescence decay study of the adsorption of nonionic surfactants at the solid-liquid interface. 2. Influence of polar chain length

Fluorescence decay study of the adsorption of nonionic surfactants at the solid-liquid interface. 1. Structure of the adsorption layer on a hydrophilic solid

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