Your search keyword '"Bacco, Davide"' showing total 7 results

1. Efficient information reconciliation for high-dimensional quantum key distribution

Author

Mueller, Ronny, Ribezzo, Domenico, Zahidy, Mujtaba, Oxenløwe, Leif Katsuo, Bacco, Davide, and Forchhammer, Søren

Published

2024

2. Photonic integrated chip enabling orbital angular momentum multiplexing for quantum communication

Author

Zahidy Mujtaba, Liu Yaoxin, Cozzolino Daniele, Ding Yunhong, Morioka Toshio, Oxenløwe Leif K., and Bacco Davide

Subjects

orbital angular momentum, quantum communication, quantum key distribution, silicon photonics, Physics, QC1-999

Abstract

Light carrying orbital angular momentum constitutes an important resource for both classical and quantum information technologies. Its inherently unbounded nature can be exploited to generate high-dimensional quantum states or for channel multiplexing in classical and quantum communication in order to significantly boost the data capacity and the secret key rate, respectively. While the big potentials of light owning orbital angular momentum have been widely ascertained, its technological deployment is still limited by the difficulties deriving from the fabrication of integrated and scalable photonic devices able to generate and manipulate it. Here, we present a photonic integrated chip able to excite orbital angular momentum modes in an 800 m long ring-core fiber, allowing us to perform parallel quantum key distribution using two and three different modes simultaneously. The experiment sets the first steps towards quantum orbital angular momentum division multiplexing enabled by a compact and light-weight silicon chip, and further pushes the development of integrated scalable devices supporting orbital angular momentum modes.

Published

2021

3. Scalable Implementation of Temporal and Phase Encoding QKD with Phase‐Randomized States.

Author

Francesconi, Saverio, De Lazzari, Claudia, Ribezzo, Domenico, Vagniluca, Ilaria, Biagi, Nicola, Occhipinti, Tommaso, Zavatta, Alessandro, and Bacco, Davide

Subjects

PHASE coding, QUANTUM theory, COHERENT states, QUANTUM states, LASER interferometers, PHOTONS

Abstract

Quantum key distribution (QKD), that is, exchanging cryptographic keys encoded in quantum particles exploiting the laws of quantum physics, is already a reality in our society. Current implementations are based on attenuated laser technique, a practical replacement of single photons which requires a random phase for each quantum state in order to achieve the highest level of security. In particular, the time‐bin and phase encoding techniques are mainly exploiting laser in gain‐switching modes combined with asymmetric interferometers or multiple laser sources in a master–slave configuration, which present limitations in terms of stability and scalability. In this work, a novel scheme for implementing a reconfigurable and scalable QKD transmitter based on the time‐bin encoding protocol with a decoy‐state method employing phase‐randomized weak coherent states is proposed and demonstrated. The scheme is tested and validated up to 26 dB‐attenuation channel using standard single‐photon detectors working in the telecom wavelength range. [ABSTRACT FROM AUTHOR]

Published

2024

4. Photonic integrated chip enabling orbital angular momentum multiplexing for quantum communication.

Author

Zahidy, Mujtaba, Liu, Yaoxin, Cozzolino, Daniele, Ding, Yunhong, Morioka, Toshio, Oxenløwe, Leif K., and Bacco, Davide

Subjects

QUANTUM communication, ANGULAR momentum (Mechanics), QUANTUM states

Abstract

Light carrying orbital angular momentum constitutes an important resource for both classical and quantum information technologies. Its inherently unbounded nature can be exploited to generate high-dimensional quantum states or for channel multiplexing in classical and quantum communication in order to significantly boost the data capacity and the secret key rate, respectively. While the big potentials of light owning orbital angular momentum have been widely ascertained, its technological deployment is still limited by the difficulties deriving from the fabrication of integrated and scalable photonic devices able to generate and manipulate it. Here, we present a photonic integrated chip able to excite orbital angular momentum modes in an 800 m long ring-core fiber, allowing us to perform parallel quantum key distribution using two and three different modes simultaneously. The experiment sets the first steps towards quantum orbital angular momentum division multiplexing enabled by a compact and light-weight silicon chip, and further pushes the development of integrated scalable devices supporting orbital angular momentum modes. [ABSTRACT FROM AUTHOR]

Published

2022

5. Quantum Key Distribution Networks: Challenges and Future Research Issues in Security.

Author

Tsai, Chia-Wei, Yang, Chun-Wei, Lin, Jason, Chang, Yao-Chung, Chang, Ruay-Shiung, and Bacco, Davide

Subjects

RSA algorithm, COMPUTER network security, SECURITY management, RESEARCH institutes, CRYPTOGRAPHY

Abstract

A quantum key distribution (QKD) network is proposed to allow QKD protocols to be the infrastructure of the Internet for distributing unconditional security keys instead of existing public-key cryptography based on computationally complex mathematical problems. Numerous countries and research institutes have invested enormous resources to execute correlation studies on QKD networks. Thus, in this study, we surveyed existing QKD network studies and practical field experiments to summarize the research results (e.g., type and architecture of QKD networks, key generating rate, maximum communication distance, and routing protocol). Furthermore, we highlight the three challenges and future research issues in the security of QKD networks and then provide some feasible resolution strategies for these challenges. [ABSTRACT FROM AUTHOR]

Published

2021

6. Stable Transmission of High-Dimensional Quantum States Over a 2-km Multicore Fiber.

Author

Da Lio, Beatrice, Oxenlowe, Leif Katsuo, Bacco, Davide, Cozzolino, Daniele, Biagi, Nicola, Arge, Tummas Napoleon, Larsen, Emil, Rottwitt, Karsten, Ding, Yunhong, and Zavatta, Alessandro

Abstract

High-dimensional quantum states have already settled their advantages in different quantum technology applications. However, their reliable transmission in fiber links remains an open challenge that must be addressed to boost their application, e.g. in the future quantum internet. Here, we prove how path encoded high-dimensional quantum states can be reliably transmitted over a 2 km long multicore fiber, taking advantage of a phase-locked loop system guaranteeing a stable interferometric detection. [ABSTRACT FROM AUTHOR]

Published

2020

7. Deploying an Inter-European quantum network

Author

Domenico Ribezzo, Mujtaba Zahidy, Ilaria Vagniluca, Nicola Biagi, Saverio Francesconi, Tommaso Occhipinti, Leif K. Oxenløwe, Martin Lončarić, Ivan Cvitić, Mario Stipčević, Žiga Pušavec, Rainer Kaltenbaek, Anton Ramšak, Francesco Cesa, Giorgio Giorgetti, Francesco Scazza, Angelo Bassi, Paolo De Natale, Francesco Saverio Cataliotti, Massimo Inguscio, Davide Bacco, Alessandro Zavatta, Ribezzo, Domenico, Zahidy, Mujtaba, Vagniluca, Ilaria, Biagi, Nicola, Francesconi, Saverio, Occhipinti, Tommaso, Oxenløwe, Leif K., Lončarić, Martin, Cvitić, Ivan, Stipčević, Mario, Pušavec, Žiga, Kaltenbaek, Rainer, Ramšak, Anton, Cesa, Francesco, Giorgetti, Giorgio, Scazza, Francesco, Bassi, Angelo, De Natale, Paolo, Cataliotti, Francesco Saverio, Inguscio, Massimo, Bacco, Davide, and Zavatta, Alessandro

Subjects

Quantum Physics, Nuclear and High Energy Physics, Physics, QKD, European quantum communication infrastructure, fibre optic network, quantum communication, quantum communication field trial, quantum internet, quantum key distribution, quantum network, FOS: Physical sciences, Statistical and Nonlinear Physics, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, Quantum criptography, Quantum communication, Computational Theory and Mathematics, Electrical and Electronic Engineering, Quantum Physics (quant-ph), Mathematical Physics

Abstract

Around forty years have passed since the first pioneering works have introduced the possibility of using quantum physics to strongly enhance communications safety. Nowadays Quantum Cryptography, and in particular, Quantum Key Distribution (QKD) exited the physics laboratories to become commercial technologies that increasingly trigger the attention of States, military forces, banks, and private corporations. This work takes on the challenge of bringing QKD closer to a consumer technology: optical fibers deployed and used by telecommunication companies of different States have been used to realize a quantum network, the first-ever connecting three different countries. This pushes towards the necessary coexistence of QKD and classical communications on the same infrastructure, which currently represents a main limit of this technology. Our network connects Trieste to Rijeka and Ljubljana via a trusted node in Postojna; a key rate of over 3 kbps has been achieved in the shortest link, and a 7-hour long measurement has demonstrated the system stability and reliability. Finally, the network has been used for a public demonstration of QKD at the G20 Digital Ministers' Meeting in Trieste. The reported experimental results, together with the significant interest that one of the most important events of international politics has attracted, showcase the maturity of the QKD technology bundle, placing it in the spotlight for consumer applications in the near term., Comment: 8 pages, 3 figures

Published

2022