Indistinguishable photons from the resonance fluorescence of a single quantum dot in a microcavity

TL;DR

This paper demonstrates the generation of highly indistinguishable, near Fourier transform-limited photons from a single quantum dot in a microcavity using resonant excitation, highlighting its potential for quantum photonics applications.

Contribution

It introduces a method for resonant excitation of a quantum dot in a microcavity to produce highly indistinguishable photons with suppressed dephasing, advancing quantum light source technology.

Findings

Achieved near Fourier transform-limited photon emission with 90% visibility.

Demonstrated the evolution from single emission line to Mollow triplet under increasing pump power.

Showed Purcell-enhancement suppresses pure dephasing, improving photon indistinguishability.

Abstract

We demonstrate purely resonant continuous-wave optical laser excitation to coherently prepare an excitonic state of a single semiconductor quantum dot (QDs) inside a high quality pillar microcavity. As a direct proof of QD resonance fluorescence, the evolution from a single emission line to the characteristic Mollow triplet10 is observed under increasing pump power. By controlled utilization of weak coupling between the emitter and the fundamental cavity mode through Purcell-enhancement of the radiative decay, a strong suppression of pure dephasing is achieved, which reflects in close to Fourier transform-limited and highly indistinguishable photons with a visibility contrast of 90%. Our experiments reveal the model-like character of the coupled QD-microcavity system as a promising source for the generation of ideal photons at the quantum limit. From a technological perspective, the vertical cavity symmetry -- with optional dynamic tunability -- provides strongly directed light emission which appears very desirable for future integrated emitter devices.