Asynchronous Entanglement Routing for the Quantum Internet

TL;DR

This paper introduces asynchronous routing protocols for quantum networks that improve entanglement distribution efficiency over traditional synchronized methods, leveraging dynamic topologies inspired by classical lossy network routing.

Contribution

It proposes novel asynchronous routing protocols for quantum repeaters that enhance entanglement rates by maintaining dynamic topologies and optimizing entanglement-swapping paths.

Findings

Asynchronous protocols achieve higher entanglement rates than synchronous ones.

Entanglement rate increases with coherence time.

Protocols significantly improve quantum network efficiency.

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.