Thermodynamics and dynamics of atomic self-organization in an optical cavity

TL;DR

This paper investigates the thermodynamics and dynamics of atomic self-organization in an optical cavity, revealing it as a second-order phase transition with out-of-equilibrium steady states and quantum noise effects, supported by a self-consistent theoretical framework.

Contribution

It introduces a comprehensive theory describing atomic self-organization in optical cavities, including quantum noise effects and the shot-noise limit, extending previous models.

Findings

Selforganization is a second-order phase transition.

The steady state is a thermal state controlled by laser detuning and cavity loss.

Quantum noise causes jumps between ordered patterns.

Abstract

Pattern formation of atoms in high-finesse optical resonators results from the mechanical forces of light associated with superradiant scattering into the cavity mode. It occurs when the laser intensity exceeds a threshold value, such that the pumping processes counteract the losses. We consider atoms driven by a laser and coupling with a mode of a standing-wave cavity and describe their dynamics with a Fokker-Planck equation, in which the atomic motion is semiclassical but the cavity field is a full quantum variable. The asymptotic state of the atoms is a thermal state, whose temperature is solely controlled by the detuning between the laser and the cavity frequency and by the cavity loss rate. From this result we derive the free energy and show that in the thermodynamic limit selforganization is a second-order phase transition. The order parameter is the field inside the resonator, to which one can associate a magnetization in analogy to ferromagnetism, the control field is the laser intensity, however the steady state is intrinsically out-of-equilibrium. In the symmetry-broken phase quantum noise induces jumps of the spatial density between two ordered patterns: We characterize the statistical properties of this temporal behaviour at steady state and show that the thermodynamic properties of the system can be extracted by detecting the light at the cavity output. The results of our analysis are in full agreement with previous studies, extend them by deriving a self-consistent theory which is valid also when the cavity field is in the shot-noise limit, and elucidate the nature of the selforganization transition.