Polarization-Independent Zero Directional Scattering Without Geometric Symmetries

TL;DR

This paper demonstrates a method to achieve polarization-independent zero directional scattering in nanophotonics without relying on geometric symmetries, by analyzing quasi-normal modes in non-Hermitian systems.

Contribution

It introduces a novel approach using quasi-normal modes and geometric phase to realize polarization-independent scattering without geometric symmetries.

Findings

Zero directional scattering can be achieved independently of incident polarization.

The method does not require geometric symmetries in the scattering structures.

Utilizes electromagnetic reciprocity and geometric phase for control of scattering.

Abstract

As the characteristic feature of generalized Kerker effect in Mie theory, directional scattering elimination has been playing a pivotal role in nanophotonics and many other photonic disciplines, such as singular optics and topological photonics. Generally, zero directional scattering can be obtained only for a specific incident polarization, and to make it fully independent of arbitrary polarizations would require scatterers that exhibit geometric (\textit{e.g.} mirror) symmetries. Here we revisit the generalized Kerker effect and directional scattering elimination from the perspective of not the conventional electromagnetic multipoles, but rather quasi-normal modes supported by non-Hermitian systems. We reveal how to obtain zero directional scattering that is independent of arbitrary incident polarizations, even for scattering structures that do not exhibit the required geometric symmetries. Such geometric symmetry-free and polarization-independent responses are made accessible through a synchronous exploitation of electromagnetic reciprocity and geometric phase. Our discovery can stimulate fundamental explorations and practical applications in not only photonics, but also many other wave physics branches where scattering and geometric phase are pervasive.