学术文献库

We consider the scattering of electromagnetic waves by non-spherical dielectric resonators and reveal that it can be linked to the exceptional points underpinned by the physics of non-Hermitian systems. We demonstrate how symmetry breaking in the shape of an isolated dielectric nanoparticle can be associated with the existence of an exceptional point in the eigenvalue spectrum and formulate the general conditions for the strong coupling of resonances, illustrating them for the example of the electric dipole and magnetic dipole modes supported by a silicon nanoparticle. We argue that any two modes of a dielectric nanoparticle can lead to an exceptional point provided their resonant frequencies cross as a function of a tuning parameter, such as, e.g. its aspect ratio, and their field distributions should have opposite signs after a reflection in the transverse plane of the structure. The coupled modes radiate as a mixture of electric and magnetic dipoles, which result in a strong magnetoelectric response, being easily controlled by the symmetry breaking perturbation. We also investigate the influence of a dielectric substrate, demonstrating how the latter provides an additional mechanism to tune the position of exceptional points in the parameter space. Finally, we discuss applications of magnetoelectric exceptional points for refractive index sensing.