Fluid-solid mixtures and electrochemomechanics: The simplicity of lagrangian mixture theory

Jacques M. Huyghe; R. Van Loon; F. T.P. Baaijens

doi:10.1590/s1807-03022004000200008

Fluid-solid mixtures and electrochemomechanics: The simplicity of lagrangian mixture theory

Jacques M. Huyghe
, R. Van Loon
, F. T.P. Baaijens

Eindhoven University of Technology

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

Abstract

Today, the focus of physical scientists is shifting more to biology than ever before. A biological tissue is typically an ionised porous medium saturated with a solution of ions and neutral solutes. Because classical porous media theories do not account for ionisation, the present paper addresses this issue. The characteristic pore size in most biological applications is close to the molecular level and hence below the Debye-Hueckel scale. Not only pressure gradients and concentration gradients, but electrical gradients as well are intimately linked to fluid flow, ion flow and deformation.

Original language	English
Pages (from-to)	235-258
Number of pages	24
Journal	Computational and Applied Mathematics
Volume	23
Issue number	2-3
DOIs	https://doi.org/10.1590/s1807-03022004000200008
Publication status	Published - 2004
Externally published	Yes

Keywords

Cartilage
Equipresence
Finite deformation
Shale
Swelling

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10.1590/s1807-03022004000200008

Cite this

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abstract = "Today, the focus of physical scientists is shifting more to biology than ever before. A biological tissue is typically an ionised porous medium saturated with a solution of ions and neutral solutes. Because classical porous media theories do not account for ionisation, the present paper addresses this issue. The characteristic pore size in most biological applications is close to the molecular level and hence below the Debye-Hueckel scale. Not only pressure gradients and concentration gradients, but electrical gradients as well are intimately linked to fluid flow, ion flow and deformation.",

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AU - Baaijens, F. T.P.

PY - 2004

Y1 - 2004

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AB - Today, the focus of physical scientists is shifting more to biology than ever before. A biological tissue is typically an ionised porous medium saturated with a solution of ions and neutral solutes. Because classical porous media theories do not account for ionisation, the present paper addresses this issue. The characteristic pore size in most biological applications is close to the molecular level and hence below the Debye-Hueckel scale. Not only pressure gradients and concentration gradients, but electrical gradients as well are intimately linked to fluid flow, ion flow and deformation.

KW - Cartilage

KW - Equipresence

KW - Finite deformation

KW - Shale

KW - Swelling

UR - https://www.scopus.com/pages/publications/33748333753

U2 - 10.1590/s1807-03022004000200008

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JO - Computational and Applied Mathematics

JF - Computational and Applied Mathematics

IS - 2-3

ER -

Fluid-solid mixtures and electrochemomechanics: The simplicity of lagrangian mixture theory

Abstract

Keywords

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