Scattering of electromagnetic waves by small impedance particles of an arbitrary shape

Abstract

An explicit formula is derived for the electromagnetic (EM) field scattered by one small impedance particle D of an arbitrary shape. If a is the characteristic size of the particle, λ is the wavelength, a<<λ and ζ is the boundary impedance of D, [N,[E,N]]=ζ [N,H] on S, where S is the surface of the particle, N is the unit outer normal to S, and E, H is the EM field, then the scattered field is Esc=[∇ g(x,x1), Q]. Here g(x,y)=eik|x-y|4π |x-y|, k is the wave number, x1∈ D is an arbitrary point, and Q=-ζ |S|iω μτ ∇ × E0, where E0 is the incident field, |S| is the area of S, ω is the frequency, μ is the magnetic permeability of the space exterior to D, and τ is a tensor which is calculated explicitly. The scattered field is O(|ζ| a2)>> O(a3) as a 0 when λ is fixed and ζ does not depend on a. Thus, |Esc| is much larger than the classical value O(a3) for the field scattered by a small particle. It is proved that the effective field in the medium, in which many small particles are embedded, has a limit as a 0 and the number M=M(a) of the particles tends to ∞ at a suitable rate. Thislimit solves a linear integral equation. The refraction coefficient of the limiting medium is calculated analytically. This yields a recipe for creating materials with a desired refraction coefficient.