Dynamic realization of emergent high-dimensional optical vortices

TL;DR

This paper demonstrates the creation and observation of high-dimensional optical vortical structures within a specially designed optical cavity, advancing the understanding of topological phenomena in photonics and enabling new device functionalities.

Contribution

The study introduces a high-dimensional gradient thickness optical cavity that realizes topological interactions across multiple dimensions, leading to the experimental observation of high-dimensional optical vortices.

Findings

Observation of high-dimensional vortical structures in 3D and 4D parameter spaces

Demonstration of topological transitions of optical vortices

Programmable optical vortex dynamics in four-dimensional structures

Abstract

The dimensionality of vortical structures has recently been extended beyond two dimensions, providing higher-order topological characteristics and robustness for high-capacity information processing and turbulence control. The generation of high-dimensional vortical structures has mostly been demonstrated in classical systems through the complex interference of fluidic, acoustic, or electromagnetic waves. However, natural materials rarely support three- or higher-dimensional vortical structures and their physical interactions. Here, we present a high-dimensional gradient thickness optical cavity (GTOC) in which the optical coupling of planar metal-dielectric multilayers implements topological interactions across multiple dimensions. Topological interactions in high-dimensional GTOC construct non-trivial topological phases, which induce high-dimensional vortical structures in generalized parameter space in three, four dimensions, and beyond. These emergent high-dimensional vortical structures are observed under electro-optic tomography as optical vortex dynamics in two-dimensional real-space, employing the optical thicknesses of the dielectric layers as synthetic dimensions. We experimentally demonstrate emergent vortical structures, optical vortex lines and vortex rings, in a three-dimensional generalized parameter space and their topological transitions. Furthermore, we explore four-dimensional vortical structures, termed optical vortex sheets, which provide the programmability of real-space optical vortex dynamics. Our findings hold significant promise for emulating high-dimensional physics and developing active topological photonic devices.