An efficient source of continuous variable polarisation entanglement

TL;DR

This paper demonstrates an efficient method to generate highly entangled bipartite continuous variable polarisation states using Kerr non-linearity in glass fibres, with strong quantum noise correlations verified through Stokes parameter measurements.

Contribution

The authors present a novel, optimized scheme for producing polarisation entanglement via Kerr non-linearity, achieving significant squeezing and robust entanglement verification.

Findings

Achieved -4.1 dB squeezing below shot noise in certain Stokes parameters.

Demonstrated entanglement robustness against beam splitter asymmetries.

Verified quantum correlations in multiple conjugate Stokes parameter sets.

Abstract

We have experimentally demonstrated the efficient creation of highly entangled bipartite continuous variable polarisation states. Exploiting an optimised scheme for the production of squeezing using the Kerr non-linearity of a glass fibre we generated polarisation squeezed pulses with a mean classical excitation in S3. Polarisation entanglement was generated by interfering two independent polarisation squeezed fields on a symmetric beam splitter. The resultant beams exhibit strong quantum noise correlations in the dark S1 - S2 polarisation plane. To verify entanglement generation, we characterised the quantum correlations of the system for two different sets of conjugate Stokes parameters. The quantum correlations along the squeezed and the anti-squeezed Stokes parameters were observed to be -4.1 +/- 0.3 dB and -2.6 +/- 0.3 dB below the shot noise level respectively. The degree of correlations was found to depend critically on the beam splitting ratio of the entangling beam splitter. Carrying out measurements on a different set of conjugate Stokes parameters, correlations of -3.6 +/- 0.3 dB and -3.4 +/- 0.3 dB have been observed. This result is more robust against asymmetries in the entangling beam splitter, even in the presence of excess noise.