Superradiant and Dark Exciton States in an Optical Lattice within a Cavity

Abstract

We study ultracold atoms in a finite size one-dimensional optical lattice prepared in the Mott insulator phase and commonly coupled to a single cavity mode. Due to resonance dipole-dipole interactions among the atoms, electronic excitations delocalize and form excitons. These exciton modes are divided into two groups: antisymmetric modes which decouple from the cavity mode forming dark states, and symmetric modes significantly coupled to the cavity mode called bright states. In typical setups the lowest and most symmetric exciton is coupled to the cavity photons much stronger than the other bright states and dominates the optical properties response of the atoms ( superradiant state). In the strong coupling regime this superradiant state is coherently mixed with the cavity photon to form a doublet of polariton states with the Rabi splitting.