Mean-chiral displacement in coherently driven photonic lattices and its application to synthetic frequency dimensions

TL;DR

This paper proposes a method to measure topological invariants in driven-dissipative photonic lattices using a generalized mean-chiral displacement, enabling the detection of winding numbers even with losses, especially in synthetic frequency dimensions.

Contribution

It introduces a novel approach to extend the mean-chiral displacement for topological characterization in lossy, driven photonic systems, applicable to synthetic frequency dimensions.

Findings

The method accurately estimates winding numbers with minimal correction due to losses.

It is experimentally feasible with coherent illumination in driven-dissipative systems.

Successfully demonstrated in synthetic frequency dimension lattices.

Abstract

Characterizing topologically nontrivial photonic lattices by measuring their topological invariants is crucial in topological photonics. In conservative one-dimensional systems, a widely used observable to extract the winding number is the mean-chiral displacement. In many realistic photonic systems, however, losses can hardly be avoided, and little is known on how one can extend the mean-chiral displacement to a driven-dissipative context. Here we theoretically propose an experimentally viable method to directly detect the topological winding number of one-dimensional chiral photonic lattices. The method we propose is a generalization of the mean-chiral displacement to a driven-dissipative context with coherent illumination. By integrating the mean-chiral displacement of the steady state over the pump light frequency, one can obtain the winding number with a correction of the order of the loss rate squared. We demonstrate that this method can be successfully applied to lattices along synthetic frequency dimensions.