English

Asynchronous Entanglement Routing for the Quantum Internet

Networking and Internet Architecture 2024-01-19 v1 Quantum Physics

Abstract

With the emergence of the Quantum Internet, the need for advanced quantum networking techniques has significantly risen. Various models of quantum repeaters have been presented, each delineating a unique strategy to ensure quantum communication over long distances. We focus on repeaters that employ entanglement generation and swapping. This revolves around establishing remote end-to-end entanglement through repeaters, a concept we denote as the "quantum-native" repeaters (also called "first-generation" repeaters in some literature). The challenges in routing with quantum-native repeaters arise from probabilistic entanglement generation and restricted coherence time. Current approaches use synchronized time slots to search for entanglement-swapping paths, resulting in inefficiencies. Here, we propose a new set of asynchronous routing protocols for quantum networks by incorporating the idea of maintaining a dynamic topology in a distributed manner, which has been extensively studied in classical routing for lossy networks, such as using a destination-oriented directed acyclic graph (DODAG) or a spanning tree. The protocols update the entanglement-link topology asynchronously, identify optimal entanglement-swapping paths, and preserve unused direct-link entanglements. Our results indicate that asynchronous protocols achieve a larger upper bound with an appropriate setting and significantly higher entanglement rate than existing synchronous approaches, and the rate increases with coherence time, suggesting that it will have a much more profound impact on quantum networks as technology advances.

Keywords

Cite

@article{arxiv.2312.14300,
  title  = {Asynchronous Entanglement Routing for the Quantum Internet},
  author = {Zebo Yang and Ali Ghubaish and Raj Jain and Hassan Shapourian and Alireza Shabani},
  journal= {arXiv preprint arXiv:2312.14300},
  year   = {2024}
}

Comments

This article has been accepted for publication in the AVS Quantum Science journal

R2 v1 2026-06-28T13:59:18.841Z