From Non-scattering to Super-scattering with the Topology of Light and Matter

TL;DR

This paper explores how the topology of incident light and matter in dielectric meta-atoms can induce both non-scattering and super-scattering states, revealing new regimes of light-matter interaction with potential applications in optics and spectroscopy.

Contribution

It demonstrates the control of scattering states in dielectric meta-atoms through light and matter topology, introducing hybrid anapole states and switching mechanisms between scattering regimes.

Findings

Hybrid anapole states suppress far-field radiation.

Switching between non-scattering and super-scattering states is achievable.

Topological effects influence scattering responses in meta-atoms.

Abstract

Electric anapole states, arising due to the destructive interferences of primitive and toroidal electric dipole moments, have been recently introduced as the fundamental class of non-scattering sources with several potential applications ranging from nonlinear optics to thermodynamics thanks to their field confinement and minimal scattering fingerprints. Nevertheless, other non-radiating sources are also possible and can provide significant energy confinement at the nanoscale if they spectrally overlap with their electrical counterparts. On the other hand, super-scattering states represent the opposite regime of light-matter interaction wherein the scattering cross-section of a particular multipolar moment exceeds the single-channel limit, leading to a strong scattering in the direction of the pump beam. Here, we demonstrate that the interplay between the topology of incident light and the subwavelength scatterer can lead to these two opposite regimes of light-matter interactions within an isolated all-dielectric meta-atom. In particular, we show that the presented scatterer can support new non-scattering states, called hybrid anapole, leading to significant suppression of the far-field radiation and enhancement of electromagnetic energy inside the meta-atom. We also explore the role of particle orientation and its inversion symmetry on the scattering response and show how switching between non-scattering to super-scattering states can occur within the same platform. The presented study elucidates the role of light and matter topologies in the scattering response of subwavelength meta-atoms and reveals the formation of two extreme opposite regimes of light-matter interaction, opening new avenues in several applications ranging from nonlinear optics to spectroscopy.