Quantum Routing Beyond Pathfinding: Multipartite Entanglement Complementation
Abstract
Conventional quantum routing operates under the entrenched assumption that pathfinding is a prerequisite for routing. This classical-inspired routing model imposes a restricting design option, which prevents scaling the quantumness to the network functioning. In this paper, we proposed a novel entanglement-driven routing framework that exploits multipartite entanglement complementation for enabling simultaneous 1-hop connectivity among all non-adjacent source-destination pairs. This changes the notion of ``remoteness'' in the entanglement graph, activated by entanglement. We extend this framework to inter-domain quantum networks and design a polynomial-time algorithm. Such an algorithm allows to select and parallelize multiple requests, bypassing NP-complete path discovery. Performance analysis shows the proposed routing strategy achieves up to hop reduction, with the algorithm enabling efficient parallelism and strong scalability in inter-domain quantum networks.
Cite
@article{arxiv.2604.13834,
title = {Quantum Routing Beyond Pathfinding: Multipartite Entanglement Complementation},
author = {Si-Yi Chen and Angela Sara Cacciapuoti and Marcello Caleffi},
journal= {arXiv preprint arXiv:2604.13834},
year = {2026}
}
Comments
This work has been funded by the European Union under Horizon Europe ERC-CoG grant QNattyNet ("Quantum-Native Communication Networks: from Quantum Message to Quantum Functioning''), n.101169850. Details at https://qnattynet.quantuminternet.it