Observation of Light Guiding by Artificial Gauge Fields

TL;DR

This paper experimentally demonstrates light guiding using artificial gauge fields in photonic waveguide arrays, revealing new mechanisms for confinement and bound states in the continuum with potential applications across various physical systems.

Contribution

First experimental demonstration of waveguiding via artificial gauge fields in photonics, utilizing waveguide geometry and phase-shifted trajectories to achieve confinement.

Findings

Waveguiding achieved by tilting waveguides to create gauge fields.

Bound states in the continuum realized through phase-shifted gauge trajectories.

Artificial gauge fields enable novel light confinement mechanisms.

Abstract

The use of artificial gauge fields enables systems of uncharged particles to behave as if affected by external fields. Generated by geometry or external modulation, artificial gauge fields have been instrumental in demonstrating topological phenomena in many physical systems, including photonics, cold atoms and acoustic waves. Here, we demonstrate experimentally for the first time waveguiding by means of artificial gauge fields. To this end, we construct artificial gauge fields in a photonic waveguide array, by using waveguides with nontrivial trajectories. First, we show that tilting the waveguide arrays gives rise to gauge fields that are different in the core and the cladding, shifting their respective dispersion curves, and in turn confining the light to the core. In a more advanced setting, we demonstrate waveguiding in a medium with the same artificial gauge field and the same dispersion everywhere, but with a phase-shift in the gauge as the only difference between the core and the cladding. The phase-shifted sinusoidal trajectories of the waveguides give rise to waveguiding via bound states in the continuum. Creating waveguiding and bound states in the continuum by means of artificial gauge fields is relevant to a wide range of physical systems, ranging from photonics and microwaves to cold atoms and acoustics.