On a class of three-phase checkerboards with unusual effective properties

Abstract

We examine the band spectrum, and associated Floquet-Bloch eigensolutions, arising in a class of three-phase periodic checkerboards. On a periodic cell [-1,1[2, the refractive index is defined by n2= 1+ g1(x1)+g2(x2) with gi(xi)= r2 for 0≤ xi<1, and gi(xi)= 0 for -1≤ xi≤ 0 where r2 is constant. We find that for r2>-1 the lowest frequency branch goes through origin with linear behaviour, which leads to effective properties encountered in most periodic structures. However, the case whereby r2=-1 is very unusual, as the frequency λ behaves like k near the origin, where k is the wavenumber. Finally, when r2<-1, the lowest branch does not pass through the origin and a zero-frequency band gap opens up. In the last two cases, effective medium theory breaks down even in the quasi-static limit, while the high-frequency homogenization [Craster et al., Proc. Roy. Soc. Lond. A 466, 2341-2362, 2010] neatly captures the detailed features of band diagrams.