Generalised Maxwell-Garnett equation: Application to electrical and chemical transport

J. Jamnik; J. R. Kalnin; E. A. Kotomin; J. Maier

doi:10.1039/b514448p

Generalised Maxwell-Garnett equation: Application to electrical and chemical transport

J. Jamnik
, J. R. Kalnin
, E. A. Kotomin
, J. Maier^*

^*Corresponding author for this work

Laboratory of Kinetics in Self-Organizing Systems, Institute of Solid State Physics

National Institute of Chemistry Ljubljana
University of Latvia
Max Planck Institute for Solid State Research

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

31 Citations (Scopus)

Abstract

In this paper we discuss the implementation of different equilibrium concentrations in each of the phases into the Maxwell-Garnett effective medium formula for diffusion in heterogeneous media. We put the derivation given by Kalnin et al., J. Phys. Chem. Solids, 2002, 63, 449, on safer grounds and extend it to non-dilute carrier concentrations. The relation to Maxwell's mixing rule is also elaborated. It is shown that the formula can not only successfully be applied to conductivity problems but also to describe steady state chemical diffusion in heterogeneous media such as polycrystalline samples. The comparison with the brick layer model corroborates these points but also shows that - in the case of heterogeneous media - one has to be cautious in applying steady state results to transient kinetics.

Original language	English
Pages (from-to)	1310-1314
Number of pages	5
Journal	Physical Chemistry Chemical Physics
Volume	8
Issue number	11
DOIs	https://doi.org/10.1039/b514448p
Publication status	Published - 2006

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T2 - Application to electrical and chemical transport

AU - Jamnik, J.

AU - Kalnin, J. R.

AU - Kotomin, E. A.

AU - Maier, J.

PY - 2006

Y1 - 2006

N2 - In this paper we discuss the implementation of different equilibrium concentrations in each of the phases into the Maxwell-Garnett effective medium formula for diffusion in heterogeneous media. We put the derivation given by Kalnin et al., J. Phys. Chem. Solids, 2002, 63, 449, on safer grounds and extend it to non-dilute carrier concentrations. The relation to Maxwell's mixing rule is also elaborated. It is shown that the formula can not only successfully be applied to conductivity problems but also to describe steady state chemical diffusion in heterogeneous media such as polycrystalline samples. The comparison with the brick layer model corroborates these points but also shows that - in the case of heterogeneous media - one has to be cautious in applying steady state results to transient kinetics.

AB - In this paper we discuss the implementation of different equilibrium concentrations in each of the phases into the Maxwell-Garnett effective medium formula for diffusion in heterogeneous media. We put the derivation given by Kalnin et al., J. Phys. Chem. Solids, 2002, 63, 449, on safer grounds and extend it to non-dilute carrier concentrations. The relation to Maxwell's mixing rule is also elaborated. It is shown that the formula can not only successfully be applied to conductivity problems but also to describe steady state chemical diffusion in heterogeneous media such as polycrystalline samples. The comparison with the brick layer model corroborates these points but also shows that - in the case of heterogeneous media - one has to be cautious in applying steady state results to transient kinetics.

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VL - 8

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JO - Physical Chemistry Chemical Physics

JF - Physical Chemistry Chemical Physics

IS - 11

ER -

Generalised Maxwell-Garnett equation: Application to electrical and chemical transport

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