Scattering asymmetry and circular dichroism in coupled PT-symmetric chiral nanoparticles

We investigate the scattering properties of coupled parity-time (PT) symmetric chiral nanospheres with scattering matrix formalism. The exceptional points, i.e., spectral singularities at which the eigenvalues and eigenvectors simultaneously coalesce in the parameter space, of scattering matrix can be tailored by the chirality of the nanospheres. We also calculate the scattering, absorption and extinction cross sections of the PT-symmetric chiral scatter under illumination by monochromatic left- and right-circularly polarized plane waves. We find that the scattering cross section of the nanostructures exhibits an asymmetry when the plane waves are incident from the loss and gain regions, respectively, especially in the broken phase, and the optical cross section exhibits circular dichroism, i.e., differential extinction when the PT-symmetric scatter is endowed with chirality. In particular, under illumination by linearly polarized monochromatic plane waves without intrinsic chirality, the ellipticity of scattered fields in the forward direction, denoting the chirality of light, becomes larger when the scatter is in the PT-symmetry-broken phase. Our findings demonstrate that the gain and loss can control the optical chirality and enhance the chiroptical interactions and pave the way for studying the resonant chiral light-matter interactions in non-Hermitian photonics.

Automated summary

In this study, the scattering properties of coupled parity-time (PT) symmetric chiral nanospheres were investigated using a scattering matrix formalism. The results showed that the scattering cross section exhibited asymmetry under different incident light environments, while the optical cross section displayed circular dichroism, especially when the PT-symmetric scatter possessed chirality. Additionally, gain and loss were found to control optical chirality, enhancing chiroptical interactions and paving the way for studying resonant chiral light-matter interactions in non-Hermitian photonics.