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Main Authors: Wallnöfer, Julius, Hahn, Frederik, Wiesner, Fabian, Walk, Nathan, Eisert, Jens
Format: Preprint
Published: 2022
Subjects:
Online Access:https://arxiv.org/abs/2212.03896
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author Wallnöfer, Julius
Hahn, Frederik
Wiesner, Fabian
Walk, Nathan
Eisert, Jens
author_facet Wallnöfer, Julius
Hahn, Frederik
Wiesner, Fabian
Walk, Nathan
Eisert, Jens
contents Quantum repeaters have long been established to be essential for distributing entanglement over long distances. Consequently, their experimental realization constitutes a core challenge of quantum communication. However, there are numerous open questions about implementation details for realistic, near-term experimental setups. In order to assess the performance of realistic repeater protocols, we here present ReQuSim, a comprehensive Monte-Carlo based simulation platform for quantum repeaters that faithfully includes loss and models a wide range of imperfections such as memories with time-dependent noise. Our platform allows us to perform an analysis for quantum repeater setups and strategies that go far beyond known analytic results: This refers to being able to both capture more realistic noise models and analyse more complex repeater strategies. We present a number of findings centered around the combination of strategies for improving performance, such as entanglement purification and the use of multiple repeater stations, and demonstrate that there exist complex relationships between them. We stress that numerical tools such as ours are essential to model complex quantum communication protocols aimed at contributing to the quantum internet.
format Preprint
id arxiv_https___arxiv_org_abs_2212_03896
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle ReQuSim: Faithfully simulating near-term quantum repeaters
Wallnöfer, Julius
Hahn, Frederik
Wiesner, Fabian
Walk, Nathan
Eisert, Jens
Quantum Physics
Quantum repeaters have long been established to be essential for distributing entanglement over long distances. Consequently, their experimental realization constitutes a core challenge of quantum communication. However, there are numerous open questions about implementation details for realistic, near-term experimental setups. In order to assess the performance of realistic repeater protocols, we here present ReQuSim, a comprehensive Monte-Carlo based simulation platform for quantum repeaters that faithfully includes loss and models a wide range of imperfections such as memories with time-dependent noise. Our platform allows us to perform an analysis for quantum repeater setups and strategies that go far beyond known analytic results: This refers to being able to both capture more realistic noise models and analyse more complex repeater strategies. We present a number of findings centered around the combination of strategies for improving performance, such as entanglement purification and the use of multiple repeater stations, and demonstrate that there exist complex relationships between them. We stress that numerical tools such as ours are essential to model complex quantum communication protocols aimed at contributing to the quantum internet.
title ReQuSim: Faithfully simulating near-term quantum repeaters
topic Quantum Physics
url https://arxiv.org/abs/2212.03896