Dissipation in quasistatically sheared wet and dry sand under confinement

J. E. Fiscina; M. Pakpour; A. Fall; N. Vandewalle; C. Wagner; D. Bonn

doi:10.1103/PhysRevE.86.020103

Dissipation in quasistatically sheared wet and dry sand under confinement

J. E. Fiscina
, M. Pakpour
, A. Fall
, N. Vandewalle
, C. Wagner
, D. Bonn

Research output: Contribution to journal › Article › peer-review

Abstract

We investigated the stress-strain behavior of sand with and without small amounts of liquid under steady and oscillatory shear. Since dry sand has a lower shear modulus, one would expect it to deform more easily. Using a new technique to quasistatically push the sand through a tube with an enforced parabolic (Poiseuille-like) profile, we minimize the effect of avalanches and shear localization. We observe that the resistance against deformation of the wet (partially saturated) sand is much smaller than that of the dry sand, and that the latter dissipates more energy under flow. This is also observed in large-amplitude oscillatory shear measurements using a rotational rheometer, showing that the effect is robust and holds for different types of flow.

Original language	English
Article number	020103
Journal	Physical Review E - Statistical, Nonlinear, and Soft Matter Physics
Volume	86
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevE.86.020103
Publication status	Published - 24 Aug 2012
Externally published	Yes

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10.1103/PhysRevE.86.020103

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title = "Dissipation in quasistatically sheared wet and dry sand under confinement",

abstract = "We investigated the stress-strain behavior of sand with and without small amounts of liquid under steady and oscillatory shear. Since dry sand has a lower shear modulus, one would expect it to deform more easily. Using a new technique to quasistatically push the sand through a tube with an enforced parabolic (Poiseuille-like) profile, we minimize the effect of avalanches and shear localization. We observe that the resistance against deformation of the wet (partially saturated) sand is much smaller than that of the dry sand, and that the latter dissipates more energy under flow. This is also observed in large-amplitude oscillatory shear measurements using a rotational rheometer, showing that the effect is robust and holds for different types of flow.",

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AU - Fiscina, J. E.

AU - Pakpour, M.

AU - Fall, A.

AU - Vandewalle, N.

AU - Wagner, C.

AU - Bonn, D.

PY - 2012/8/24

Y1 - 2012/8/24

N2 - We investigated the stress-strain behavior of sand with and without small amounts of liquid under steady and oscillatory shear. Since dry sand has a lower shear modulus, one would expect it to deform more easily. Using a new technique to quasistatically push the sand through a tube with an enforced parabolic (Poiseuille-like) profile, we minimize the effect of avalanches and shear localization. We observe that the resistance against deformation of the wet (partially saturated) sand is much smaller than that of the dry sand, and that the latter dissipates more energy under flow. This is also observed in large-amplitude oscillatory shear measurements using a rotational rheometer, showing that the effect is robust and holds for different types of flow.

AB - We investigated the stress-strain behavior of sand with and without small amounts of liquid under steady and oscillatory shear. Since dry sand has a lower shear modulus, one would expect it to deform more easily. Using a new technique to quasistatically push the sand through a tube with an enforced parabolic (Poiseuille-like) profile, we minimize the effect of avalanches and shear localization. We observe that the resistance against deformation of the wet (partially saturated) sand is much smaller than that of the dry sand, and that the latter dissipates more energy under flow. This is also observed in large-amplitude oscillatory shear measurements using a rotational rheometer, showing that the effect is robust and holds for different types of flow.

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JO - Physical Review E - Statistical, Nonlinear, and Soft Matter Physics

JF - Physical Review E - Statistical, Nonlinear, and Soft Matter Physics

IS - 2

M1 - 020103

ER -

Dissipation in quasistatically sheared wet and dry sand under confinement

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