Spontaneous generation and active manipulation of real-space optical vortex

TL;DR

This paper demonstrates the spontaneous creation and magnetic field control of optical vortices in a specially designed multilayer cavity, revealing new topological and dynamic properties for photonic applications.

Contribution

It introduces a novel GTOC structure enabling topological phase transitions and magnetic manipulation of optical vortices and antivortices in real space.

Findings

Optical vortices can be generated spontaneously in the GTOC.

External magnetic fields can manipulate vortex dynamics.

Topological phases influence vortex behavior.

Abstract

Optical vortices host the orbital nature of photons, which offers an extra degree of freedom in photonic applications. Unlike vortices in other physical entities, optical vortices require structural singularities, which restrict their abilities in terms of dynamic and interactive characteristics. In this study, we present the spontaneous generation and external magnetic field-induced manipulation of an optical vortex and antivortex. A gradient-thickness optical cavity (GTOC) consisting of an Al/SiO2/Ni/SiO2 multilayer structure realised the distinct transition between the trivial and non-trivial topological phases, depending on the magneto-optic effects of the Ni layer. In the non-trivial topological phase, the mathematical singularities generating the optical vortex and antivortex pair in the reflected light existed in the generalised parameter space of the thicknesses of the top and bottom SiO2 layers, which is bijective to the real space of the GTOC. Coupled with the magnetisation, the optical vortex and antivortex in the GTOC experienced an effective spin-orbit interaction and showed topology-dependent dynamics under external magnetic fields. We expect that field-induced engineering of optical vortices will pave the way for the study of topological photonic interactions and their applications.