Related papers: Experimental composable key distribution using discrete-modulated continuous variable quantum cryptography

Experimental composable key distribution using discrete-modulated continuous variable quantum cryptography

URL: http://arxiv.org/abs/2410.13702v1
Date: Thu, 17 Oct 2024 16:05:08 GMT
Title: Experimental composable key distribution using discrete-modulated continuous variable quantum cryptography
Authors: Adnan A. E. Hajomer, Florian Kanitschar, Nitin Jain, Michael Hentschel, Runjia Zhang, Norbert Lütkenhaus, Ulrik L. Andersen, Christoph Pacher, Tobias Gehring,
Abstract summary: We present the first experimental demonstration of a four-state DM CVQKD system, successfully generating composable finite-size keys. This accomplishment is enabled by using an advanced security proof. Results mark a significant step toward the large-scale deployment of practical, high-performance, cost-effective, and highly secure quantum key distribution networks.
Score: 1.9464379888286716
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Abstract: Establishing secure data communication necessitates secure key exchange over a public channel. Quantum key distribution (QKD), which leverages the principles of quantum physics, can achieve this with information-theoretic security. The discrete modulated (DM) continuous variable (CV) QKD protocol, in particular, is a suitable candidate for large-scale deployment of quantum-safe communication due to its simplicity and compatibility with standard high-speed telecommunication technology. Here, we present the first experimental demonstration of a four-state DM CVQKD system, successfully generating composable finite-size keys, secure against collective attacks over a 20 km fiber channel with 2.3 \times 10^{9} coherent quantum states, achieving a positive composable key rate of 11.04 \times 10^{-3} bits/symbol. This accomplishment is enabled by using an advanced security proof, meticulously selecting its parameters, and the fast, stable operation of the system. Our results mark a significant step toward the large-scale deployment of practical, high-performance, cost-effective, and highly secure quantum key distribution networks using standard telecommunication components.

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