Topological valley transport under long-range deformations

TL;DR

This paper explores how topological edge states in photonic crystals behave under long-range deformations, revealing their robustness and challenges in excitation methods, with experimental validation in microwave systems.

Contribution

It introduces the study of topological photonic crystals under long-range deformations, analyzing their robustness and excitation challenges, supported by experimental microwave demonstrations.

Findings

Topological bandgap closes with increasing deformation.

Chiral sources are sensitive to lattice order.

Linearly polarized sources detect topological transport in deformed systems.

Abstract

Edge states protected by bulk topology of photonic crystals show robustness against short-range disorder, making robust information transfer possible. Here, topological photonic crystals under long-range deformations are investigated. Vertices of each regular hexagon in a honeycomb crystalline structure are shifted randomly to establish a deformed system. By increasing the degree of random deformations, a transition from an ordered system to an amorphous system are investigated, where the close of topological bandgap is clearly shown. We further present comprehensive investigations into excitation methods of the proposed deformed system. Due to the lack of strict periodicity, excitation of topological edge modes becomes difficult. Chiral and linearly polarized sources as two different methods are investigated respectively. It is found that chiral sources are sensitive and rely on the ordered lattice. Even a weak long-range deformation can bring fluctuations to transmission. We further designed and fabricated metal-dielectric-metal sandwich-like samples working in the microwave band. Using linearly polarized source, we detected the existence of topological transport in the deformed system. This work investigates excitation and robustness of bulk topology against long-range deformations and may open the way for exploiting topological properties of materials with a deformed lattice.