Complex switching dynamics of interacting light in a ring resonator

TL;DR

This paper analyzes the complex nonlinear and chaotic switching behaviors in a coupled light resonator system, revealing bifurcation structures and transitions that inform practical applications of optical chaos.

Contribution

It provides a detailed dynamical systems analysis of chaos and switching in a coupled optical resonator, identifying bifurcation mechanisms and global bifurcation organization.

Findings

Identification of bifurcation points leading to chaos

Mapping of switching behaviors via bifurcation diagrams

Explanation of global bifurcations like Shilnikov and Belyakov transitions

Abstract

Microresonators are micron-scale optical systems that confine light using total internal reflection. These optical systems have gained interest in the last two decades due to their compact sizes, unprecedented measurement capabilities, and widespread applications. The increasingly high finesse (or $Q$ factor) of such resonators means that nonlinear effects are unavoidable even for low power, making them attractive for nonlinear applications, including optical comb generation and second harmonic generation. In addition, light in these nonlinear resonators may exhibit chaotic behavior across wide parameter regions. Hence, it is necessary to understand how, where, and what types of such chaotic dynamics occur before they can be used in practical devices. We consider a pair of coupled differential equations that describes the interactions of two optical beams in a single-mode resonator with symmetric pumping. Recently, it was shown that this system exhibits a wide range of fascinating behaviors, including bistability, symmetry breaking, chaos, and self-switching oscillations. We employ here a dynamical system approach to identify, delimit, and explain the regions where such different behaviors can be observed. Specifically, we find that different kinds of self-switching oscillations are created via the collision of a pair of asymmetric periodic orbits or chaotic attractors at Shilnikov homoclinic bifurcations, which acts as a gluing bifurcation. We present a bifurcation diagram that shows how these global bifurcations are organized by a Belyakov transition point (where the stability of the homoclinic orbit changes). In this way, we map out distinct transitions to different chaotic switching behavior that should be expected from this optical device.