Photonic Higher-Order Topological States Induced by Long Range Interactions

TL;DR

This paper demonstrates a 2D photonic higher-order topological insulator using a distorted Kagome lattice, revealing new corner states sustained by long-range interactions that enhance topological robustness and physics richness.

Contribution

It introduces a 2D photonic HOTI with long-range interaction-induced corner states, expanding the understanding of topological protection in photonics beyond nearest neighbor effects.

Findings

Discovery of 0D corner states due to long-range interactions

Presence of topological edge states in the Kagome lattice

Enhanced topological robustness in photonic HOTIs

Abstract

The discovery of topological phases has recently led to a paradigm shift in condensed matter physics, and facilitated breakthroughs in engineered photonics and acoustic metamaterials. Topological insulators (TIs) enable the generation of electronic, photonic, and acoustic modes exhibiting wave propagation that is resilient to disorder, irrespective of manufacturing precision or unpredictable defects induced by the operational environment, known as topological protection. While originally limited to a dimensionality of the protected states that is one dimension lower than the host TI material, the recent discovery of higher-order topological insulators (HOTIs) provides the potential to overcome this dimensionality limitations by offering topological protection over an extended range of dimensionalities. Here we demonstrate 2D photonic HOTI (PHOTI) with topological states two dimensions lower than the one of the host system. We consider a photonic metacrystal of distorted Kagome lattice geometry that exhibits topological bulk polarization, leading to the emergence of 1D topological edge states and of higher order 0D states confined to the corners of the structure. Interestingly, in addition to corner states due to the nearest neighbour interactions and protected by generalized chiral symmetry 1, we discover and take advantage of a new class of topological corner states sustained by long-range interactions, available in wave-based systems, such as in photonics. Our findings demonstrate that photonic HOTIs possess richer physics compared to their condensed matter counterparts, offering opportunities for engineering novel designer electromagnetic states with unique topological robustness.