Spontaneous symmetry breaking of dissipative optical solitons in a two-component Kerr resonator

TL;DR

This paper reports the first experimental observation of spontaneous symmetry breaking in dissipative optical solitons within a Kerr resonator, revealing new ways to manipulate light states for photonic applications.

Contribution

It demonstrates spontaneous symmetry breaking of dissipative solitons in a Kerr resonator and shows how to control these states for optical switching and information processing.

Findings

Symmetry breaking leads to two co-existing vectorial solitons with asymmetric polarization.

Perturbations enable deterministic switching between symmetry-broken states.

Experimental results agree with numerical simulations and theoretical models.

Abstract

Dissipative solitons are self-localised structures that can persist indefinitely in "open" systems characterised by continual exchange of energy and/or matter with the environment. They play a key role in photonics, underpinning technologies from mode-locked lasers to microresonator optical frequency combs. Here we report on the first experimental observations of spontaneous symmetry breaking of dissipative optical solitons. Our experiments are performed in a passive, coherently driven nonlinear optical ring resonator, where dissipative solitons arise in the form of persisting pulses of light known as Kerr cavity solitons. We engineer balance between two orthogonal polarization modes of the resonator, and show that despite perfectly symmetric operating conditions, the solitons supported by the system can spontaneously break their symmetry, giving rise to two distinct but co-existing vectorial solitons with mirror-like, asymmetric polarization states. We also show that judiciously applied perturbations allow for deterministic switching between the two symmetry-broken dissipative soliton states, thus enabling all-optical manipulation of topological bit sequences. Our experimental observations are in excellent agreement with numerical simulations and theoretical analyses. Besides delivering fundamental insights at the intersection of multi-mode nonlinear optical resonators, dissipative structures, and spontaneous symmetry breaking, our work provides new avenues for the storage, coding, and manipulation of light.