Quantum stabilization of photonic spatial correlations

TL;DR

This paper investigates how quantum correlations influence the stability of antiferromagnetic phases in driven-dissipative photonic systems, revealing that quantum fluctuations can stabilize new homogeneous states beyond mean-field predictions.

Contribution

It introduces a self-consistent $1/z$ expansion method to analyze quantum correlations in the dissipative Bose-Hubbard model, demonstrating stabilization of antiferromagnetic correlations.

Findings

Quantum fluctuations stabilize a new homogeneous steady-state.

Antiferromagnetic correlations manifest as short-range oscillations.

Mean-field theory predictions are modified by quantum effects.

Abstract

The driven, dissipative Bose-Hubbard model (BHM) provides a generic description of collective phases of interacting photons in cavity arrays. In the limit of strong optical nonlinearities (hard-core limit), the BHM maps on the dissipative, transverse-field XY model (XYM). The steady-state of the XYM can be analyzed using mean-field theory, which reveals a plethora of interesting dynamical phenomena. For example, strong hopping combined with a blue-detuned drive, leads to an instability of the homogeneous steady-state with respect to antiferromagnetic fluctuations. In this paper, we address the question whether such an antiferromagnetic instability survives in the presence of quantum correlations beyond the mean-field approximation. For that purpose, we employ a self-consistent $1/z$ expansion for the density matrix, where $z$ is the lattice coordination number, i.e., the number of nearest neighbours for each site. We show that quantum fluctuations stabilize a new homogeneous steady-state with antiferromagnetic correlations in agreement with exact numerical simulations for finite lattices. The latter manifests itself as short-ranged oscillations of the first and second-order spatial coherence functions of the photons emitted by the array.