Quantum theory of polariton weak lasing and polarization bifurcations

The quantum theory of polariton condensation in a trapped state reveals a second-order phase transition evidenced by spontaneous polarization parity breaking in sub-spaces of fixed polariton occupation numbers. The emission spectra of polariton condensate demonstrate the coexistence of the symmetry-conserving condensate state with the linear X polarization and the symmetry-broken, elliptically polarized states in the vicinity of the threshold. As a result, the oscillating linear second-order coherence $g^{(2)}_{xx}(t)$, with $g^{(2)}_{xx}(t)<1$ over some time intervals, is obtained. The spontaneous symmetry breaking is reflected in the second-order cross correlator of circular polarizations. The related build-up of elliptically-polarized weak lasing results also in non-monotonous dependence of the circular second-order coherence on the excitation power and the interaction strength.