Quantum dot single photon sources with ultra-low multi-photon probability
Abstract
High-quality sources of single photons are of paramount importance for quantum communication, sensing and metrology. To these ends, resonantly excited two-level systems based on self-assembled quantum dots have recently generated widespread interest. Nevertheless, we have recently shown that for resonantly excited two-level systems, emission of a photon during the presence of the excitation laser pulse and subsequent re-excitation results in a degradation of the obtainable single-photon purity. Here, we demonstrate that generating single photons from self-assembled quantum dots with a scheme based on two-photon excitation of the biexciton strongly suppresses the re-excitation. Specifically, the pulse-length dependence of the multi-photon error rate reveals a quadratic dependence in contrast to the linear dependence of resonantly excited two-level systems, improving the obtainable multi-photon error rate by several orders of magnitude for short pulses. We support our experiments with a new theoretical framework and simulation methodology to understand few-photon sources.
Cite
@article{arxiv.1801.01672,
title = {Quantum dot single photon sources with ultra-low multi-photon probability},
author = {Lukas Hanschke and Kevin A. Fischer and Stefan Appel and Daniil Lukin and Jakob Wierzbowski and Shuo Sun and Rahul Trivedi and Jelena Vučković and Jonathan J. Finley and Kai Müller},
journal= {arXiv preprint arXiv:1801.01672},
year = {2018}
}
Comments
We have included a Jupyter notebook as Supplemental Material which outlines how to perform the calculations in this paper using the Quantum Optics Toolbox in Python (QuTiP)