Homogenization of a stationary periodic Maxwell system in a bounded domain in the case of constant magnetic permeability

Abstract

In a bounded domain O⊂R3 of class C1,1, we consider a stationary Maxwell system with the boundary conditions of perfect conductivity. It is assumed that the magnetic permeability is given by a constant positive (3× 3)-matrix μ0 and the dielectric permittivity is of the form η( x/ ), where η( x) is a (3 × 3)-matrix-valued function with real entries, periodic with respect to some lattice, bounded and positive definite. Here >0 is the small parameter. Suppose that the equation involving the curl of the magnetic field intensity is homogeneous, and the right-hand side r of the second equation is a divergence-free vector-valued function of class L2. It is known that, as 0, the solutions of the Maxwell system, namely, the electric field intensity u, the electric displacement vector w, the magnetic field intensity v, and the magnetic displacement vector z weakly converge in L2 to the corresponding homogenized fields u0, w0, v0, z0 (the solutions of the homogenized Maxwell system with effective coefficients). We improve the classical results. It is shown that v and z converge to v0 and z0, respectively, in the L2-norm, the error terms do not exceed C \| r\|L2. We also find approximations for v and z in the energy norm with error C \| r\|L2. For u and w we obtain approximations in the L2-norm with error C \| r\|L2.