Bérangère Delourme

Bérangère Delourme, Patrick Joly, Elizaveta Vasilevskaya

In this note, we exhibit a three dimensional structure that permits to guide waves. This structure is obtained by a geometrical perturbation of a 3D periodic domain that consists of a three dimensional grating of equi-spaced thin pipes oriented along three orthogonal directions. Homogeneous Neumann boundary conditions are imposed on the boundary of the domain. The diameter of the section of the pipes, of order $ε$ \textgreater{} 0, is supposed to be small. We prove that, for $ε$ small enough, shrinking the section of one line of the grating by a factor of $\sqrt$ $μ$ (0 \textless{} $μ$ \textless{} 1) creates guided modes that propagate along the perturbed line. Our result relies on the asymptotic analysis (with respect to $ε$) of the spectrum of the Laplace-Neumann operator in this structure. Indeed, as $ε$ tends to 0, the domain tends to a periodic graph, and the spectrum of the associated limit operator can be computed explicitly.

Bérangère Delourme, David P. Hewett

In this note we consider the scattering of electromagnetic waves (governed by the time-harmonic Maxwell equations) by a thin periodic layer of perfectly conducting obstacles. The size of the obstacles and the distance between neighbouring obstacles are of the same small order of magnitude $δ$, $δ$ being small. By deriving homogenized interface conditions for three model configurations, namely (i) discrete obstacles, (ii) parallel wires, (iii) a wire mesh, we show that the limiting behaviour as $δ\to0$ depends strongly on the topology of the periodic layer, with full shielding (the so-called "Faraday cage effect") occurring only in the case of a wire mesh.