Generating coherence and entanglement with a finite-size atomic ensemble in a ring cavity

TL;DR

This paper models how a finite-size atomic ensemble in a ring cavity can induce coherence and entanglement between counter-propagating modes, revealing effects absent in the thermodynamic limit.

Contribution

It introduces a finite-size model that captures spatial variations and predicts new coherence and entanglement phenomena in atomic ensembles.

Findings

Counter-propagating modes become mutually coherent after interaction with finite-size ensemble

Finite size causes nonorthogonality of collective bosonic modes and super-bunching effects

Entanglement concentrates at zero-frequency component in the spectrum

Abstract

We propose a model to study the coherence and entanglement resulting from the interaction of a finite-size atomic ensemble with degenerate counter-propagating field modes of a high-Q ring cavity. Our approach applies to an arbitrary number of atoms N and includes the spatial variation of the field throughout the ensemble. We report several new interesting aspects of coherence and entangled behavior that emerge when the size of the atomic ensemble is not taken to the thermodynamic limit of N>>1. Under such conditions, it is found that the counter-propagating cavity modes, although in the thermodynamic limit are mutually incoherent and exhibit no one-photon interference, the modes can, however, be made mutually coherent and exhibit interference after interacting with a finite-size atomic ensemble. It is also found that the spatial redistribution of the atoms over a finite size results in nonorthogonality of the collective bosonic modes. This nonorthogonality leads to the super-bunching effect that the correlations of photons of the individual cavity modes and of different modes are stronger than those of a thermal field. However, we find that the correlations are not strong enough to violate the Cauchy-Schwarz inequality and to produce squeezing and entanglement between the modes. Therefore, we investigate the spectral distributions of the logarithmic negativity and the variances of the output fields. These functions determine squeezing and entanglement properties of the output cavity fields and can be measured by a homodyne technique. We find that the entanglement is redistributed over several components of the spectrum and the finite-size effect is to concentrate the entanglement at the zero-frequency component of the spectrum.