Doctoral Training Network for Quantum Enhanced Optical Communication Network Security

Informations projet

QuNEST

N° de convention de subvention: 101120422

DOI

10.3030/101120422

Date de signature de la CE 20 Juin 2023

Date de début 1 Octobre 2023

Date de fin 30 Septembre 2027

Financé au titre de

Marie Skłodowska-Curie Actions (MSCA)

Coût total

Aucune donnée

Contribution de l’UE

€ 2 661 328,80

Coordonné par

TECHNISCHE UNIVERSITEIT EINDHOVEN
Netherlands

CORDIS fournit des liens vers les livrables publics et les publications des projets HORIZON.

Les liens vers les livrables et les publications des projets du 7e PC, ainsi que les liens vers certains types de résultats spécifiques tels que les jeux de données et les logiciels, sont récupérés dynamiquement sur OpenAIRE .

Livrables

D2.3 Impact of classical channel configuration on QKD security

Impact of classical channel impairments on the QKD security

D2.2 Implementation security for DV- and CV-QKD

Establishing and extending the security proofs for DV- and CV-QKD

D2.1 A detailed survey on state of the art and emerging QKD protocols

A detailed survey on state of the art and emerging QKD protocols

D1.1 Identification of methods, channel assumptions for impairments and implications on security

Identification of methods, channel assumptions for impairments (e.g., SRS, SBS,scattering effects, thermal/shot noise) and implications on security

D1.2 Description of the state-of-the-art simulation capabilities for weak coherent based QKD systems

Description of the state-of-the-art simulation capabilities for weak coherent-based QKD systems

D3.3 Low-rate Coding for classical and quantum channels

Low-rate coding for classical and quantum channels

D4.3 Control plane considerations for coexisting transport of QKD

Control plane considerations for coexisting transport of QKD

D3.1 Detailed analysis of DV- and CV-QKD signal processing requirements

Detailed analysis of DV- and CV-QKD signal processing requirements

Publications

Protograph-Based LDPC Codes with Local Irregularity

Auteurs: Vincent Wüst,Erdem Eray Cil, Laurent Schmalen
Publié dans: Proc. International Symposium on Information Theory (ISIT), 2025
Éditeur: IEEE
DOI: 10.48550/ARXIV.2505.17837

Hybrid Time-Path High-Dimensional Quantum Key Distribution in Multicore Fibers: Addressing Crosstalk and Enhancing Performance Metrics

Auteurs: Ian Korobov, Piotr Novik, Igor Koltchanov
Publié dans: 2025 25th Anniversary International Conference on Transparent Optical Networks (ICTON), 2025
Éditeur: IEEE
DOI: 10.1109/ICTON67126.2025.11124835

Accurate and Effective Model for Coexistence of Classical and Quantum Signals In Optical Fibers

Auteurs: Lucas Alves Zischler, Çağla Özkan, Tristan Vosshenrich, Qi Wu, Giammarco Di Sciullo, Divya A. Shaji, Chiara Lasagni, Paolo Serena, Alberto Bononi, Amirhossein Ghazisaeidi, Chigo Okonkwo, Antonio Me
Publié dans: Journal of Lightwave Technology, 2025
Éditeur: Arxiv
DOI: 10.48550/ARXIV.2510.02807

Integration of quantum key distribution and high-throughput classical communications in field-deployed multi-core fibers

Auteurs: Qi Wu, Domenico Ribezzo, Giammarco Di Sciullo, Sebastiano Cocchi, Divya Ann Shaji, Lucas Alves Zischler, Ruben Luis, Paolo Serena, Chiara Lasagni, Alberto Bononi, Tetsuya Hayashi, Alessandro Gagliano,
Publié dans: Light: Science & Applications, Numéro 14, 2025, ISSN 2047-7538
Éditeur: Springer Science and Business Media LLC
DOI: 10.1038/S41377-025-01982-Z

Accurate and Effective Model for Coexistence of Classical and Quantum Signals In Optical Fibers

Auteurs: Lucas Alves Zischler, Çağla Özkan, Tristan Vosshenrich, Qi Wu, Giammarco Di Sciullo, Divya A. Shaji, Chiara Lasagni, Paolo Serena, Alberto Bononi, Amirhossein Ghazisaeidi, Chigo Okonkwo, Antonio Me
Publié dans: 2025
Éditeur: Journal of Lightwave Technology
DOI: 10.48550/ARXIV.2510.02807

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