Experimental evidence for transparency, band gaps and Anderson localization in two-dimensional hyperuniform disordered photonic materials.

The recent prediction of full photonic bandgaps in amorphous dielectric materials is surprising since it defies the picture of bandgap formation by reflections and interferences from Bragg planes in a periodically repeating environment. Numerical work on stealthy hyperuniform solids also suggested that disordered photonic materials can display additional transport regimes: the same material can show transparency, photon diffusion, Anderson localization, or a full bandgap, depending on the frequency $\nu$ of the electromagnetic wave. Here we demonstrate experimentally, using microwaves, that the density of states and the different transport properties can be observed and quantified in a two-dimensional hyperuniform disordered array of cylinders with high dielectric permittivity. Interestingly, we find a second weaker bandgap at higher frequencies, which can be linked to higher-order spatial correlations and the second peak in the structure factor. Our results emphasize the importance of spatial correlations for the formation of photonic band gaps.