Space-Based Quantum Internet: Entanglement Distribution in Time-Varying LEO Constellations

TL;DR

This paper proposes a novel entanglement distribution framework for LEO satellite networks that leverages their dynamic topology, improving efficiency and resilience for quantum internet applications.

Contribution

It introduces a space-time graph model and a path utility-based strategy that accounts for real-world link imperfections, enhancing entanglement distribution in moving satellite constellations.

Findings

Reduces entanglement drop rates significantly

Increases end-to-end throughput in LEO networks

Demonstrates robustness against pointing errors and atmospheric effects

Abstract

This paper addresses the complexities of entanglement distribution in LEO satellite networks, particularly those arising from their dynamic topology. Traditional static and dynamic entanglement distribution methods often result in high entanglement drop rates and reduced end-to-end throughput. We introduce a novel framework that leverages the dynamic nature of LEO satellite networks to enhance entanglement distribution efficiency. Employing a space-time graph model to represent the network's temporal evolution, we propose an entanglement distribution strategy based on path utility, incorporating pointing errors, non-ideal link transmittance for intersatellite links, and atmospheric effects for downlinks. Our approach demonstrates superior performance in reducing entanglement drop rates and improving throughput compared to conventional methods. This study advances the field of quantum communication in satellite networks, offering resilient and efficient entanglement distribution strategies that support practical applications such as distributed computing, quantum multipartite cryptography, and distributed quantum sensing. The findings underscore the potential of integrating dynamic satellite networks with quantum technologies to create a reliable and secure quantum internet.