Incipient dynamics of swelling of gels

Hang Zhang; M. Carme Calderer

doi:10.1137/070680941

Incipient dynamics of swelling of gels

Hang Zhang, M. Carme Calderer

Mathematics

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11 Scopus citations

Abstract

In this article, we analyze a model of the incipient dynamics of gel swelling and perform numerical simulations. The governing system consists of balance laws for a mixture of nonlinear elastic solid and solvent yielding effective equations for the gel. We discuss the multiscale nature of the problem and identify physically realistic regimes. The mixing mechanism is based on the Flory-Huggins energy. We consider the case that the dissipation mechanism is the solid-solvent friction force. This leads to a system of weakly dissipative nonlinear hyperbolic equations. After addressing the Cauchy problem, we propose physically realistic boundary conditions describing the motion of the swelling boundary. We study the linearized version of the free boundary problem. Numerical simulations of solutions are presented too.

Original language	English (US)
Pages (from-to)	1641-1664
Number of pages	24
Journal	SIAM Journal on Applied Mathematics
Volume	68
Issue number	6
DOIs	https://doi.org/10.1137/070680941
State	Published - 2008

Keywords

Gel swelling
Hyperbolic free boundary problem
Polymer-solvent friction
Two-component mixture
Type II diffusion

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AB - In this article, we analyze a model of the incipient dynamics of gel swelling and perform numerical simulations. The governing system consists of balance laws for a mixture of nonlinear elastic solid and solvent yielding effective equations for the gel. We discuss the multiscale nature of the problem and identify physically realistic regimes. The mixing mechanism is based on the Flory-Huggins energy. We consider the case that the dissipation mechanism is the solid-solvent friction force. This leads to a system of weakly dissipative nonlinear hyperbolic equations. After addressing the Cauchy problem, we propose physically realistic boundary conditions describing the motion of the swelling boundary. We study the linearized version of the free boundary problem. Numerical simulations of solutions are presented too.

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KW - Polymer-solvent friction

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Incipient dynamics of swelling of gels

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