Topological $n$-root Su-Schrieffer-Heeger model in a non-Hermitian photonic ring system

TL;DR

This paper develops a framework for designing general $n$-root topological insulators using the SSH model, introduces non-Hermitian photonic ring implementations, and explores their unique edge states within a ring gap.

Contribution

The paper extends topological insulator theory to arbitrary $n$-root models using unidirectional couplings and proposes a realistic photonic implementation with experimental validation.

Findings

Edge states appear at $n$ branches of the complex spectrum

The models feature a novel ring gap not reducible to point or line gaps

Photonic ring systems can realize high-root topological models

Abstract

Square-root topology is one of the newest additions to the ever expanding field of topological insulators (TIs). It characterizes systems that relate to their parent TI through the squaring of their Hamiltonians. Extensions to $2^n$-root topology, where $n$ is the number of squaring operations involved in retrieving the parent TI, were quick to follow. Here, we go one step further and develop the framework for designing general $n$-root TIs, with $n$ any positive integer, using the Su-Schrieffer-Heeger (SSH) model as the parent TI from which the higher-root versions are constructed. The method relies on using loops of unidirectional couplings as building blocks, such that the resulting model is non-Hermitian and embedded with a generalized chiral symmetry. Edge states are observed at the $n$ branches of the complex energy spectrum, appearing within what we designate as a ring gap, shown to be irreducible to the usual point or line gaps. We further detail on how such an $n$-root model can be realistically implemented in photonic ring systems. Near perfect unidirectional effective couplings between the main rings can be generated via mediating auxiliary rings with modulated gains and losses. These induce high imaginary gauge fields that strongly supress couplings in one direction, while enhancing them in the other. We use these photonic lattices to validate and benchmark the analytical predictions. Our results introduce a new class of high-root topological models, as well as a route for their experimental realization.