Long-distance coherent quantum communications in deployed telecom networks
成果类型:
Article
署名作者:
Pittaluga, Mirko; Lo, Yuen San; Brzosko, Adam; Woodward, Robert I.; Scalcon, Davide; Winnel, Matthew S.; Roger, Thomas; Dynes, James F.; Owen, Kim A.; Juarez, Sergio; Rydlichowski, Piotr; Vicinanza, Domenico; Roberts, Guy; Shields, Andrew J.
署名单位:
Toshiba Corporation; Polish Academy of Sciences; Poznan Supercomputing & Networking Center; Anglia Ruskin University
刊物名称:
Nature
ISSN/ISSBN:
0028-2744
DOI:
10.1038/s41586-025-08801-w
发表日期:
2025-04-24
关键词:
key distribution
state
teleportation
detectors
creation
摘要:
Recent advances in quantum communications have underscored the crucial role of optical coherence in developing quantum networks. This resource, which is fundamental to the phase-based architecture of the quantum internet1, has enabled the only successful demonstrations of multi-node quantum networks2, 3-4 and substantially extended the range of quantum key distribution (QKD)5. However, the scalability of coherence-based quantum protocols remains uncertain owing to the specialized hardware required, such as ultra-stable optical cavities and cryogenic photon detectors. Here we implement the coherence-based twin-field QKD protocol over a 254-kilometre commercial telecom network spanning between Frankfurt and Kehl, Germany, achieving encryption key distribution at 110 bits per second. Our results are enabled by a scalable approach to optical coherence distribution, supported by a practical system architecture and non-cryogenic single-photon detection aided by off-band phase stabilization. Our results demonstrate repeater-like quantum communication in an operational network setting, doubling the distance for practical real-world QKD implementations without cryogenic cooling. In addition, to our knowledge, we realized one of the largest QKD networks featuring measurement-device-independent properties6. Our research aligns the requirements of coherence-based quantum communication with the capabilities of existing telecommunication infrastructure, which is likely to be useful to the future of high-performance quantum networks, including the implementation of advanced quantum communication protocols, quantum repeaters, quantum sensing networks and distributed quantum computing7.