Water transfer and crack regimes in nanocolloidal gels

J. Thiery; S. Rodts; E. Keita; X. Chateau; P. Faure; D. Courtier-Murias; T. E. Kodger; P. Coussot

doi:10.1103/PhysRevE.91.042407

Water transfer and crack regimes in nanocolloidal gels

J. Thiery
, S. Rodts
, E. Keita
, X. Chateau
, P. Faure
, D. Courtier-Murias
, T. E. Kodger
, P. Coussot

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

Direct observations of the surface and shape of model nanocolloidal gels associated with measurements of the spatial distribution of water content during drying show that air starts to significantly penetrate the sample when the material stops shrinking. We show that whether the material fractures or not during desiccation, as air penetrates the porous body, the water saturation decreases but remains almost homogeneous throughout the sample. This air invasion is at the origin of another type of fracture due to capillary effects; these results provide insight into the liquid dynamics at the nanoscale.

langue originale	Anglais
Numéro d'article	042407
journal	Physical Review E - Statistical, Nonlinear, and Soft Matter Physics
Volume	91
Numéro de publication	4
Les DOIs	https://doi.org/10.1103/PhysRevE.91.042407
état	Publié - 27 avr. 2015
Modification externe	Oui

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10.1103/PhysRevE.91.042407

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abstract = "Direct observations of the surface and shape of model nanocolloidal gels associated with measurements of the spatial distribution of water content during drying show that air starts to significantly penetrate the sample when the material stops shrinking. We show that whether the material fractures or not during desiccation, as air penetrates the porous body, the water saturation decreases but remains almost homogeneous throughout the sample. This air invasion is at the origin of another type of fracture due to capillary effects; these results provide insight into the liquid dynamics at the nanoscale.",

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AU - Thiery, J.

AU - Rodts, S.

AU - Keita, E.

AU - Chateau, X.

AU - Faure, P.

AU - Courtier-Murias, D.

AU - Kodger, T. E.

AU - Coussot, P.

PY - 2015/4/27

Y1 - 2015/4/27

N2 - Direct observations of the surface and shape of model nanocolloidal gels associated with measurements of the spatial distribution of water content during drying show that air starts to significantly penetrate the sample when the material stops shrinking. We show that whether the material fractures or not during desiccation, as air penetrates the porous body, the water saturation decreases but remains almost homogeneous throughout the sample. This air invasion is at the origin of another type of fracture due to capillary effects; these results provide insight into the liquid dynamics at the nanoscale.

AB - Direct observations of the surface and shape of model nanocolloidal gels associated with measurements of the spatial distribution of water content during drying show that air starts to significantly penetrate the sample when the material stops shrinking. We show that whether the material fractures or not during desiccation, as air penetrates the porous body, the water saturation decreases but remains almost homogeneous throughout the sample. This air invasion is at the origin of another type of fracture due to capillary effects; these results provide insight into the liquid dynamics at the nanoscale.

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Water transfer and crack regimes in nanocolloidal gels

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