English

Homogenization and nonselfadjoint spectral optimization for dissipative Maxwell eigenproblems

Analysis of PDEs 2026-01-23 v2 Optimization and Control Spectral Theory

Abstract

The homogenization of eigenvalues of non-Hermitian Maxwell operators is studied by the H-convergence method. It is assumed that the Maxwell systems are equipped with suitable m-dissipative boundary conditions, namely, with Leontovich or generalized impedance boundary conditions of the form n×E=Z[(n×H)×n]n \times E = Z [(n \times H )\times n ] . We show that, for a wide class of impedance operators ZZ, the nonzero spectrum of the corresponding Maxwell operator is discrete. To this end, a new continuous embedding theorem for domains of Maxwell operators is obtained. We prove the convergence of eigenvalues to an eigenvalue of a homogenized Maxwell operator under the assumption of the H-convergence of the material tensor-fields. This result is used then to prove the existence of optimizers for eigenvalue optimization problems and the existence of an eigenvalue-free region around zero. As applications, connections with the quantum optics problem of the design of high-Q resonators are discussed, and a new way of the quantification of the unique (and nonunique) continuation property is suggested.

Keywords

Cite

@article{arxiv.2401.01049,
  title  = {Homogenization and nonselfadjoint spectral optimization for dissipative Maxwell eigenproblems},
  author = {Matthias Eller and Illya M. Karabash},
  journal= {arXiv preprint arXiv:2401.01049},
  year   = {2026}
}

Comments

31 pages, the discussion on connections with quantum optics and unique continuation is added, in particular, Example 2.2 (ii); 3 references are added; some of the proofs are shortened; typos are corrected

R2 v1 2026-06-28T14:06:36.649Z