Sequential vs. Simultaneous Entanglement Swapping under Optimal Link-Layer Control
Abstract
Connection-less, packet-switched quantum network architectures distribute entanglement across multi-hop paths through sequential entanglement swapping, in which each node acts on purely local state information. The architectural advantages over the connection-oriented alternative -- simultaneous SWAP-ASAP -- are compelling, but sequential swapping holds partial chains in intermediate buffers between successive swaps, exposing them to memory decoherence in a way simultaneous SWAP-ASAP avoids by design. We present a proof-of-principle study at fixed chain length in which each elementary link is governed by a fixed reinforcement-learning policy optimizing the secret-key rate of the six-state protocol, leaving the network-layer protocol as the sole independent variable. Sweeping the network-layer memory coherence time over four orders of magnitude reveals a clear regime structure governed by the dimensionless ratio , where is the per-link entanglement heralding latency. Simultaneous SWAP-ASAP delivers a constant rate across the full sweep. Sequential swapping, by contrast, collapses to zero end-to-end deliveries below , and begins recovering at . It remains limited by the simultaneous rate, which it saturates only at the relaxed end of the sweep. These results suggest that the connection-less penalty is a near-term phenomenon tied to present-day memory coherence rather than a fundamental property of sequential swapping.
Cite
@article{arxiv.2605.04047,
title = {Sequential vs. Simultaneous Entanglement Swapping under Optimal Link-Layer Control},
author = {Priyam Srivastava and Akshat R. Sabavat and Siddharth Jain and Alan Scheller-Wolf and Sridhar Tayur and David Tipper and Prashant Krishnamurthy and Amy Babay and Kaushik P. Seshadreesan},
journal= {arXiv preprint arXiv:2605.04047},
year = {2026}
}
Comments
Submitted to IEEE QCE 2026