The electrical conductivity of binary disordered systems,percolation clusters,fractals and related models |
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Authors: | JP Clerc G Giraud JM Laugier JM Luck |
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Institution: | 1. Département de Physique des Systèmes Désordonnés , Université de Provence, Centre de St-Jér?ome , 13397, Marseille Cedex 13, France;2. Département de Physique des Systèmes Désordonnés , Université de Provence, Centre de St-Jér?ome , 13397, Marseille Cedex 13, France;3. Ecole Normale , BP 4288, Antananarivo, Madagascar;4. Service de Physique Théorique (Laboratoire de l'Institut de Recherche Fondamentale du Commissariat à l'Energie Atomique), CEN Saclay , 91191, Gif-sur-Yvette Cedex, France |
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Abstract: | We review theoretical and experimental studies of the AC dielectric response of inhomogeneous materials, modelled as bond percolation networks, with a binary (conductor-dielectric) distribution of bond conductances. We first summarize the key results of percolation theory, concerning mostly geometrical and static (DC) transport properties, with emphasis on the scaling properties of the critical region around the percolation threshold. The frequency-dependent (AC) response of a general binary model is then studied by means of various approaches, including the effective-medium approximation, a scaling theory of the critical region, numerical computations using the transfer-matrix algorithm, and several exactly solvable deterministic fractal models. Transient regimes, related to singularities in the complex-frequency plane, are also investigated. Theoretical predictions are made more explicit in two specific cases, namely R-C and RL-C networks, and compared with a broad variety of experimental results, concerning, for example, granular composites, thin films, powders, microemulsions, cermets, porous ceramics and the viscoelastic properties of gels. |
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