Topological polaritons from photonic Dirac cones coupled to excitons in a magnetic field

TL;DR

This paper proposes a simplified method to create topological polaritons using photonic Dirac cones in photonic crystals, magnetic fields, and excitons, resulting in larger topological gaps and connecting to established topological photon schemes.

Contribution

The authors introduce a novel approach leveraging photonic Dirac cones to generate topological polaritons with enhanced gap sizes, simplifying previous methods and linking to topological photon concepts.

Findings

Topological gaps can be significantly increased using photonic Dirac cones.

Coupling to Zeeman-split excitons breaks time-reversal symmetry effectively.

The scheme connects topolaritons with the Haldane-Raghu topological photon model.

Abstract

We introduce an alternative scheme for creating topological polaritons (topolaritons) by exploiting the presence of photonic Dirac cones in photonic crystals with triangular lattice symmetry. As recently proposed, topolariton states can emerge from a coupling between photons and excitons combined with a periodic exciton potential and a magnetic field to open up a topological gap. We show that in photonic crystals the opening of the gap can be substantially simplified close to photonic Dirac points. Coupling to Zeeman-split excitons breaks time reversal symmetry and allows to gap out the Dirac cones in a non-trival way, leading to a topological gap similar to the strength of the periodic exciton potential. Compared to the original topolariton proposal [Karzig {\em et al}, PRX {\bf 5}, 031001 (2015)], this scheme significantly increases the size of the topological gap over a wide range of parameters. Moreover, the gap opening mechanism highlights an interesting connection between topolaritons and the Haldane and Raghu scheme [Haldane and Raghu, PRL {\bf 100}, 013904 (2008)] to create topological photons in magneto-optically active materials.