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Autor principal: Rosales, José Luis
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2605.27434
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author Rosales, José Luis
author_facet Rosales, José Luis
contents Large-scale entanglement-based quantum key distribution (QKD) networks are commonly assumed to require authentication resources scaling quadratically with the number of users. We show that realistic quantum communication networks operating under loss, decoherence, and LOCC constraints exhibit fundamentally different scaling laws. Using Pauli transfer matrix (PTM) transport, we demonstrate that Bell correlations decay exponentially along entanglement-swapping paths, generating finite operational correlation lengths and sparse operational entanglement graphs. In sparse metropolitan quantum networks, the number of CHSH-usable Bell pairs consequently scales linearly with network size, while authentication complexity scales as \[ Θ(N\log N), \] under sparse-mixing assumptions. We further present an ancilla-assisted distributed Bell-state verification framework for realistic E91 quantum metropolitan infrastructures. Our results suggest that scalable authentication in quantum communication networks emerges directly from the physics of entanglement transport.
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publishDate 2026
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spellingShingle Emergent Operational Entanglement Graphs and Sub-Quadratic Authentication Scaling in Realistic E91 Quantum Networks
Rosales, José Luis
Quantum Physics
Large-scale entanglement-based quantum key distribution (QKD) networks are commonly assumed to require authentication resources scaling quadratically with the number of users. We show that realistic quantum communication networks operating under loss, decoherence, and LOCC constraints exhibit fundamentally different scaling laws. Using Pauli transfer matrix (PTM) transport, we demonstrate that Bell correlations decay exponentially along entanglement-swapping paths, generating finite operational correlation lengths and sparse operational entanglement graphs. In sparse metropolitan quantum networks, the number of CHSH-usable Bell pairs consequently scales linearly with network size, while authentication complexity scales as \[ Θ(N\log N), \] under sparse-mixing assumptions. We further present an ancilla-assisted distributed Bell-state verification framework for realistic E91 quantum metropolitan infrastructures. Our results suggest that scalable authentication in quantum communication networks emerges directly from the physics of entanglement transport.
title Emergent Operational Entanglement Graphs and Sub-Quadratic Authentication Scaling in Realistic E91 Quantum Networks
topic Quantum Physics
url https://arxiv.org/abs/2605.27434