Scattering properties of PT-symmetric layered periodic structures

TL;DR

This paper investigates the optical properties of PT-symmetric layered structures, revealing how surface wave excitation influences tunnelling, perfect absorption, and beam dynamics, with implications for resonant phenomena and symmetry breaking.

Contribution

It provides a detailed analysis of tunnelling, surface modes, and beam dynamics in PT-symmetric periodic stacks, highlighting the effects of structure parameters and incidence conditions.

Findings

Tunnelling is linked to surface wave excitation at gain-loss boundaries.

Surface modes mediate coherent perfect absorber laser states.

Periodic structures enhance resonant phenomena and enable beam splitting.

Abstract

The optical properties of PT-symmetric periodic stack of the layers with balanced loss and gain are examined. We demonstrate that tunnelling phenomenon in periodic structures is connected with excitation of surface waves at the boundaries separating gain and loss regions within each unit cell and tunnelling conditions for periodic stack can be reduced to the conditions for one period. Alternatively, it is shown that coherent perfect absorber laser states are mediated by excitation of surface modes localised at all internal boundaries of the structure. The effects of the structure parameters and angle and direction of incidence on the resonant phenomena and spontaneous symmetry breaking transition are determined. It is shown that structure periodicity significantly increases the number of resonant phenomena, especially in stacks with high real and imaginary parts of dielectric permittivity of the layers. Gaussian beam dynamics in this type of structure is examined. The beam splitting in PT-symmetric periodic structure is observed.