Stochastic Mean-field Theory for Conditional Spin Squeezing by Homodyne Probing of Atom-Cavity Photon Dressed States

A projective measurement on a quantum system prepares an eigenstate of the observable measured. Measurements of collective observables can thus be employed to herald the preparation of entangled states of quantum systems with no mutual interactions. For large quantum systems numerical handling of the conditional quantum state by the density matrix becomes prohibitively complicated, but they may be treated by effective approximate methods. In this article, we present a stochastic variant of cumulant mean-field theory to simulate the effect of continuous optical probing of an atomic ensemble, which can be readily generalized to describe more complex systems, such as ensembles of multi-level systems and hybrid atomic and mechanical systems, and protocols that include adaptive measurements and feedback. We apply the theory to a system with tens of thousands of rubidium-87 atom in an optical cavity, and we study the spin squeezing occurring solely due to homodyne detection of a transmitted light signal near an atom-photon dressed state resonance, cf., a similar application of heterodyne detection to this system [Nat. Photonics, 8(9), 731-736 (2014)].