Topological protected defect modes in photonic crystal with a second Chern number

In the recent years, there has been a drive towards the realization of topological phases beyond conventional electronic materials, including phases defined in more than three dimensions. Photonic crystals are particularly suitable for this purpose since they can be relatively easily fabricated into a wide variety of shapes with macroscopic dimensions. We propose a way to realize 1st and 2nd Chern number topological phases with photonic crystals simply made up of defect resonators embedded within a regular lattice of resonators. Through quasiperiodic spatial modulations in the defect radii, the defect lattice can be described by a direct product of effective Hofstadter models possessing topologically nontrivial Chern bands living in four-dimensional synthetic space. Such photonic systems can be easily experimentally realized with regular photonic crystals consisting of dielectric rods in air, with topological signature measurable from kinks in the transmission spectrum caused by spectrally pumped edge states. Such topologically protected defect modes have potential applications due to their immunity towards small perturbations.