Coherent control of topological states in an integrated waveguide lattice

TL;DR

This paper demonstrates the experimental realization and coherent control of topological edge states in an integrated silicon nanostructure by exploiting accidental degeneracies and phase adjustments, enhancing robustness and tunability in topological photonics.

Contribution

It introduces a novel approach using accidental degeneracies in silicon nano-waveguides to realize and control topological edge states in integrated photonic systems.

Findings

Successful experimental realization of topological edge states.

Demonstration of phase-controlled excitation of bulk and edge states.

Quantification of mode localization via third harmonic generation.

Abstract

Topological photonics holds the promise for enhanced robustness of light localization and propagation enabled by the global symmetries of the system. While traditional designs of topological structures rely on lattice symmetries, there is an alternative strategy based on accidentally degenerate modes of the individual meta-atoms. Using this concept, we experimentally realize topological edge state in an integrated optical nanostructure based on the array of silicon nano-waveguides, each hosting a pair of degenerate modes at telecom wavelengths. Exploiting the hybrid nature of the topological mode formed by the superposition of waveguide modes with different symmetry, we implement coherent control of the topological edge state by adjusting the phase between the degenerate modes and demonstrating selective excitation of bulk or edge states. The resulting field distribution is imaged via third harmonic generation allowing us to quantify the localization of topological modes as a function of the relative phase of the excitations. Our results highlight the impact of engineered accidental degeneracies on the formation of topological phases, extending the opportunities stemming from topological nanophotonic systems.