Distilling one, two and entangled pairs of photons from a quantum dot with cavity QED effects and spectral filtering

TL;DR

This paper explores how spectral filtering and cavity effects can be used to produce high-purity, entangled photon pairs from quantum dots, emphasizing the role of leapfrog processes in enhancing quantum correlations.

Contribution

It introduces a unified theoretical framework for optimizing quantum dot photon sources through spectral filtering and cavity QED effects, highlighting leapfrog processes as key to quantum features.

Findings

Spectral filtering improves photon pair purity.

Leapfrog processes are central to quantum correlations.

Optimal configurations enhance entanglement quality.

Abstract

A quantum dot can be used as a source of one- and two-photon states and of polarisation entangled photon pairs. The emission of such states is investigated from the point of view of frequency-resolved two-photon correlations. These follow from a spectral filtering of the dot emission, which can be achieved either by using a cavity or by placing a number of interference filters before the detectors. The combination of these various options is used to iteratively refine the emission in a "distillation" process and arrive at highly correlated states with a high purity. So-called "leapfrog processes" where the system undergoes a direct transition from the biexciton state to the ground state by direct emission of two photons, are shown to be central to the quantum features of such sources. Optimum configurations are singled out in a global theoretical picture that unifies the various regimes of operation.