Pham Duc Chinh scite author profile

We extend the previous approach of one of the authors on exact strong-contrast expansions for the effective conductivity e of d-dimensional two-phase composites to case of macroscopically isotropic composites consisting of N phases. The series consists of a principal reference part and a fluctuation part ͑a perturbation about a homogeneous reference or comparison material͒, which contains multipoint correlation functions that characterize the microstructure of the composite. The fluctuation term may be estimated exactly or approximately in particular cases. We show that appropriate choices of the reference phase conductivity, such that the fluctuation term vanishes, results in simple expressions for e that coincide with the well-known effective-medium and Maxwell approximations for two-phase composites. We propose a simple three-point approximation for the fluctuation part, which agrees well with a number of analytical and numerical results, even when the contrast between the phases is infinite near percolation thresholds. Analytical expressions for the relevant three-point microstructural parameters for certain mixed coated and multicoated spheres assemblages ͑extensions of the Hashin-Shtrikman coated-spheres assemblage͒ are given. It is shown that the effective conductivity of the multicoated spheres model can be determined exactly.

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Differential multiphase models for polydispersed suspensions and particulate solids

Phan‐Thien

Chinh

1997

Journal of Non-Newtonian Fluid Mechanics

140

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Estimations of the effective conductivity of anisotropic multiphase composites with imperfect interfaces

Quang

Chinh

Bonnet

et al. 2013

International Journal of Heat and Mass Transfer

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Optimal Bounds on the Trapping Constant and Permeability of Porous Media

Torquato

Chinh

2004

Phys. Rev. Lett.

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We derive exact expressions for so-called "void" bounds on the trapping constant gamma and fluid permeability k for coated-sphere and coated-cylinder models of porous media. We find that in some cases the bounds are optimal. In these instances, exact expressions are obtained for the relevant length scale that arises in the void bounds, which depends on a two-point correlation function that characterizes the porous medium. This is the first time that model microstructures have been found that exactly realize bounds on either the trapping constant or fluid permeability.

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Estimations for the overall properties of some locally-ordered composites

Chinh

1997

Acta Mechanica

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Pham Duc Chinh

Strong-contrast expansions and approximations for the effective conductivity of isotropic multiphase composites

Differential multiphase models for polydispersed suspensions and particulate solids

Estimations of the effective conductivity of anisotropic multiphase composites with imperfect interfaces

Optimal Bounds on the Trapping Constant and Permeability of Porous Media

Estimations for the overall properties of some locally-ordered composites

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