Concentration and non-concentration of eigenfunctions of second-order elliptic operators with a divergence form in layered media

Abstract

Let ' ⊂ Rd , d = 1, 2, . . . be an open bounded smooth domain, and = '× (0,H)⊂ Rd × R+. The coordinates in are designated as x = (x ' , y) ∈ ' x (0, H). The paper deals with the concentration (and non-concentration) properties (in sectors of ) of the eigenfunctions of the self-adjoint second-order elliptic operator A = -∇·c∇ in L2(,dx) with domain D(A) = \v∈ H01(); c∇ v ∈ H1()\. The coefficient c>0 is assumed to be bounded, but no continuity assumption is imposed. It is analogous to the square of the speed of sound in the wave equation, and c is commonly known in the physical literature as the celerity. This study deals with layered media, namely, c(x)) depends only on the single spatial coordinate y ∈ (0, H), so that c(x) = c(x ' , y) = c(y). The eigenvalues of A are partitioned (apart from a small residual set) into two disjoint infinite sets. The corresponding eigenfunctions are labeled as FG (guided) and FN G (non-guided). Their asymptotic properties are expressed by suitable estimates as the associated eigenvalues tend to infinity. The eigenfunctions in FG concentrate in ''wells'' of c(y), subject to polynomial rate of decay away from the concentration sector. The non-concentrating eigenfunctions in FN G are oscillatory in every sector with non-decaying amplitudes. These results hold uniformly for families of celerities with a common bound on their total variation. The paper leaves as an open problem the question of non-concentration in the case of a function cy) which is continuous but not of bounded variation.