Exciton-polaritons in cuprous oxide: Theory and comparison with experiment

Abstract

The observation of giant Rydberg excitons in cuprous oxide (Cu2O) up to a principal quantum number of n=25 by T.~Kazimierczuk et al. [Nature 514, 343, (2014)] inevitably raises the question whether these quasi-particles must be described within a multi-polariton framework since excitons and photons are always coupled in the solid. In this paper we present the theory of exciton-polaritons in Cu2O. To this end we extend the Hamiltonian which includes the complete valence band structure, the exchange interaction, and the central-cell corrections effects, and which has been recently deduced by F.~Schweiner et al. [Phys.~Rev.~B 95, 195201, (2017)], for finite values of the exciton momentum K. We derive formulas to calculate not only dipole but also quadrupole oscillator strengths when using the complete basis of F.~Schweiner et al.. Very complex polariton spectra for the three orientations of K along the axes [001], [110], and [111] of high symmetry are obtained and a strong mixing of exciton states is reported. The main focus is on the 1S ortho exciton-polariton, for which pronounced polariton effects have been measured in experiments. We set up a 5× 5 matrix model, which accounts for both the polariton effect and the K-dependent splitting, and which allows treating the anisotropic polariton dispersion for any direction of K. We especially discuss the dispersions for K being oriented in the planes perpendicular to [110] and [111], for which experimental transmission spectra have been measured. Furthermore, we compare our results with experimental values of the K-dependent splitting, the group velocity, and the oscillator strengths of this exciton-polariton.