Effective permittivity of random plasmonic composites

Abstract

An effective-medium theory (EMT) is developed to predict the effective permittivity εeff of dense random dispersions of high optical-conductivity metals such as Ag, Au and Cu. Dependence of εeff on the volume fraction φ, a microstructure parameter related to the static structure factor and particle radius a is studied. In the electrostatic limit, the upper and lower bounds of correspond to Maxwell-Garnett and Bruggeman EMTs respectively. Finite size effects are significant when |β2(ka/n)3| becomes O(1) where β, k, and n denote the nanoparticle polarizability, wavenumber and matrix refractive index respectively. The coupling between the particle and effective medium results in a red-shift in the resonance peak, a non-linear dependence of εeff on φ, and Fano resonance in εeff.