Gigabit-rate quantum key distribution on integrated photonic chips

Abstract

Quantum key distribution (QKD) provides information-theoretic security based on the laws of quantum mechanics, offering resistance to future computational threats, including quantum computers. While QKD technology shows great promise, its widespread adoption depends heavily on achieving both high performance and system-level practicality. In this work, we report an integrated silicon photonics-based QKD system that achieves a secret key rate of Gbit s , with composable security and finite-size analysis, over a metropolitan distance of 10 km with polarization multiplexing. Our contributions are twofold. First, at the quantum optical layer, we develop an on-chip quantum transmitter and receiver that operate at 40 Gbaud at room temperature, featuring high-performance balanced homodyne detection using low-noise amplifiers with off-the-shelf RF components. Second, we implement a discrete-modulated continuous variable (DM CV) QKD protocol that simplifies hardware requirements and leverages standard telecommunication components, and design a polar-code-based information reconciliation algorithm specifically optimized for DM CV QKD and amenable to real-time implementation. Our results demonstrate a cost-effective QKD solution that achieves high key rates through integrated photonics operating at room temperature with off-the-shelf RF components and digital signal processing for robust operation. We anticipate that this research will pave the way for large-scale quantum secure networks.