Strong coupling in the sub-wavelength limit using metamaterial nanocavities

The interaction between cavity modes and optical transitions leads to new coupled light-matter states in which the energy is periodically exchanged between the matter states and the optical mode. Here we present experimental evidence of optical strong coupling between modes of individual sub-wavelength metamaterial nanocavities and engineered optical transitions in semiconductor heterostructures. We show that this behaviour is generic by extending the results from the mid-infrared (~10 μm) to the near-infrared (~1.5 μm). Using mid-infrared structures, we demonstrate that the light-matter coupling occurs at the single resonator level and with extremely small interaction volumes. We calculate a mode volume of 4.9 × 10 −4 (λ/ n ) 3 from which we infer that only ~2,400 electrons per resonator participate in this energy exchange process. Interactions between material structures and the modes of cavities they are placed in can give rise to strongly coupled light-matter states. Benz et al. show that this regime can be reached using sub-wavelength metamaterial resonators coupled to semiconductor heterostructures in the mid- and near-infrared.