Quantum motional state Dicke squeezing by cavity self-organization of ultracold atoms

We study the transverse optomechanical self-organization of an ultracold bosonic gas in a ring cavity driven by an external laser. By modeling the light-matter interaction with a many-body Hamiltonian, we demonstrate the spontaneous generation of Dicke squeezing and many-particle entanglement of atomic motional states, occurring due to self-organization of photons and atoms in the stripe phase. Once generated, these squeezed states are maintained after a sudden switch-off of the laser pump in a dissipative cavity. Our results highlight the potential of using self-organization of atomic motion as a tool for emerging quantum technologies.