Abstract
The Dicke-Ising model describes cavity quantum electrodynamics setups in which dipoles couple not only with the photonic cavity field but also with each other through dipole-dipole interaction. In this work we diagonalize such a model in terms of bosonic polaritonic operators for arbitrarily large values of the light-matter coupling and for values of the dipole-dipole interaction until the onset of the ferromagnetic Ising phase transition. In order to accomplish this task we exploit higher-order terms of the Holstein-Primakoff transformation, developing a general method which allows us to solve the normal phase of the Ising model in terms of bosonic excitations for large values of the dipole-dipole interaction. Our results shed light on the interplay between the dipole-dipole and light-matter coupling strengths and their effect on the virtual excitations which populate the ground state when the interactions become comparable with the bare transition frequency.
- Received 18 July 2017
DOI:https://doi.org/10.1103/PhysRevA.96.053861
©2017 American Physical Society