Energy-time entanglement from a resonantly driven quantum-dot three-level system

M. Hohn; K. Barkemeyer; M. von Helversen; L. Bremer; M. Gschrey; J.-H. Schulze; A. Strittmatter; A. Carmele; S. Rodt; S. Bounouar; S. Reitzenstein

doi:10.1103/PhysRevResearch.5.L022060

Physical Review Research (Jun 2023)

Energy-time entanglement from a resonantly driven quantum-dot three-level system

M. Hohn,
K. Barkemeyer,
M. von Helversen,
L. Bremer,
M. Gschrey,
J.-H. Schulze,
A. Strittmatter,
A. Carmele,
S. Rodt,
S. Bounouar,
S. Reitzenstein

Affiliations

M. Hohn
K. Barkemeyer
M. von Helversen
L. Bremer
M. Gschrey
J.-H. Schulze
A. Strittmatter
A. Carmele
S. Rodt
S. Bounouar
S. Reitzenstein

DOI: https://doi.org/10.1103/PhysRevResearch.5.L022060
Journal volume & issue: Vol. 5, no. 2
p. L022060

Abstract

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Entanglement is a major resource in advanced quantum technology where it can enable a secure exchange of information over large distances. Energy-time entanglement is particularly attractive for its beneficial robustness in fiber-based quantum communication and can be demonstrated in the Franson interferometer. We report on Franson-type interference from a resonantly driven biexciton cascade under continuous wave excitation. Our measurements yield a maximum visibility of (73±2)% surpassing the limit of violation of Bell's inequality (70.7%) by more than one standard deviation. Despite being unable to satisfy a loophole free violation, our work demonstrates promising results concerning future studies on such a system. Furthermore, our systematical investigations on the impact of driving strength indicate that dephasing mechanisms and deviations from the cascaded emission have a major impact on the degree of the measured energy-time entanglement.

Published in Physical Review Research

ISSN: 2643-1564 (Online)
Publisher: American Physical Society
Country of publisher: United States
LCC subjects: Science: Physics
Website: https://journals.aps.org/prresearch/

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