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Main Authors: Meng, Xiangyi, Hao, Bingjie, Ráth, Balázs, Kovács, István A.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2406.12228
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author Meng, Xiangyi
Hao, Bingjie
Ráth, Balázs
Kovács, István A.
author_facet Meng, Xiangyi
Hao, Bingjie
Ráth, Balázs
Kovács, István A.
contents In a quantum communication network, links represent entanglement between qubits located at different nodes. Even if two nodes are not directly linked by shared entanglement, communication channels can be established between them via quantum routing protocols. However, in contrast to classical communication networks, each communication event removes all participating links along the communication path, disrupting the quantum network. Here, we propose a simple model, where randomly selected pairs of nodes communicate through shortest paths. Each time such a path is used, all participating links are eliminated, leading to a correlated percolation process that we call ``path percolation.'' We study path percolation both numerically and analytically and present the phase diagram of the steady states as a function of the rate at which new links are being added to the quantum communication network. As a key result, the steady state is found to be independent from the initial network topology when new link are added randomly between disconnected components. We close by discussing extensions of path percolation and their potential applications.
format Preprint
id arxiv_https___arxiv_org_abs_2406_12228
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Path Percolation in Quantum Communication Networks
Meng, Xiangyi
Hao, Bingjie
Ráth, Balázs
Kovács, István A.
Quantum Physics
In a quantum communication network, links represent entanglement between qubits located at different nodes. Even if two nodes are not directly linked by shared entanglement, communication channels can be established between them via quantum routing protocols. However, in contrast to classical communication networks, each communication event removes all participating links along the communication path, disrupting the quantum network. Here, we propose a simple model, where randomly selected pairs of nodes communicate through shortest paths. Each time such a path is used, all participating links are eliminated, leading to a correlated percolation process that we call ``path percolation.'' We study path percolation both numerically and analytically and present the phase diagram of the steady states as a function of the rate at which new links are being added to the quantum communication network. As a key result, the steady state is found to be independent from the initial network topology when new link are added randomly between disconnected components. We close by discussing extensions of path percolation and their potential applications.
title Path Percolation in Quantum Communication Networks
topic Quantum Physics
url https://arxiv.org/abs/2406.12228