Creating materials with a desired refraction coefficient: numerical experiments

Abstract

A recipe for creating materials with a desired refraction coefficient is implemented numerically. The following assumptions are used: ζm=h(xm)/aκ, d=O(a(2-κ)/3), M=O(1/a2-κ), κ∈(0,1), where ζm and xm are the boundary impedance and center of the m-th ball, respectively, h(x)∈ C(D), Imh(x)≤ 0, M is the number of small balls embedded in the cube D, a is the radius of the small balls and d is the distance between the neighboring balls. An error estimate is given for the approximate solution of the many-body scattering problem in the case of small scatterers. This result is used for the estimate of the minimal number of small particles to be embedded in a given domain D in order to get a material whose refraction coefficient approximates the desired one with the relative error not exceeding a desired small quantity.