English

High-rate continuous-variable quantum key distribution over 100 km fiber with composable security

Quantum Physics 2025-03-20 v1

Abstract

Quantum key distribution (QKD), providing a way to generate secret keys with information-theoretic security,is arguably one of the most significant achievements in quantum information. The continuous-variable QKD (CV-QKD) offers the potential advantage of achieving a higher secret key rate (SKR) within a metro area, as well as being compatible with the mature telecom industry. However, the SKR and transmission distance of state-of-the-art CV-QKD systems are currently limited. Here, based on the novelly proposed orthogonal-frequency-division-multiplexing (OFDM) CV-QKD protocol, we demonstrate for the first time a high-rate multi-carrier (MC) CV-QKD with a 10 GHz symbol rate that chieves Gbps SKR within 10km and Mbps SKR over 100 km in the finite-size regime under composable security against collective attacks. The record-breaking results are achieved by suitable optimization of subcarrier number and modulation variance, well-controlled excess noise induced by both OFDM mechanism and efficient DSP scheme, and high-performance post-processing capacity realized by heterogeneous computing scheme. The composable finite-size SKR reaches 1779.45 Mbps@5km, 1025.49 Mbps@10km, 370.50 Mbps@25km, 99.93 Mbps@50km, 25.70 Mbps@75km,and 2.25 Mbps@100km, which improves the SKR by two orders of magnitude and quintuples the maximal transmission distance compared to most recently reported CV-QKD results [Nature Communications, 13, 4740 (2022)]. Interestingly, it is experimentally verified that the SKR of the proposed MC CV-QKD can approach five times larger than that of the single-carrier CV-QKD with the same symbol rate without additional hardware costs. Our work constitutes a critical step towards future high-speed quantum metropolitan and access networks.

Keywords

Cite

@article{arxiv.2503.14843,
  title  = {High-rate continuous-variable quantum key distribution over 100 km fiber with composable security},
  author = {Heng Wang and Yang Li and Ting Ye and Li Ma and Yan Pan and Mingze Wu and Junhui Li and Yiming Bian and Yaodi Pi and Yun Shao and Jie Yang and Jinlu Liu and Ao Sun and Wei Huang and Stefano Pirandola and Yichen Zhang and Bingjie Xu},
  journal= {arXiv preprint arXiv:2503.14843},
  year   = {2025}
}
R2 v1 2026-06-28T22:26:08.946Z