Average dielectric properties of discrete random media using multiple scattering theory

Author

Bringi, V. ; Varadan, Vinay

Author_Institution

Colorado State University, Fort Collins, CO, USA

Volume

31

Issue

2

fYear

1983

fDate

3/1/1983 12:00:00 AM

Firstpage

371

Lastpage

375

Abstract

Using rigorous multiple scattering theory in determining the average or bulk dielectric properties of discrete random media is the objective of this communication. The random medium is modeled as a random distribution of identical, spherical scatterers imbedded in an homogeneous unbounded background medium. At high scatterer concentration, the form of the radial distribution function becomes important; two forms are considered here, viz., virial series and the self-consistent form. The average loss tangent of the bulk medium is computed as a function of frequency and scatterer concentration, and compared with a frequently used mixture formula, e.g., Maxwell-Garnett. The results show that multiple scattering losses are significant at the higher concentrations and must be accounted for when $ka gtr\\sim 0.05$ . The theory and the computational procedure can thus he used as a mixture formula for $ka$ in the range $0 < ka \\hbox{ $_{\\sim}^{<}$} 5.0$ and concentrations in the range $0.01 < c \\hbox{ $_{\\sim}^{<}$} 0.40$ .

Keywords

Electromagnetic propagation in random media; Electromagnetic scattering by random media; Antennas and propagation; Coaxial components; Dielectrics; Dipole antennas; Frequency; Power cables; Random media; Scattering; Time factors; Transient response;

fLanguage

English

Journal_Title

Antennas and Propagation, IEEE Transactions on

Publisher

ieee

ISSN

0018-926X

Type

jour

DOI

10.1109/TAP.1983.1143034

Filename

1143034