Yang Li

Quantum key distribution (QKD) enables secure communication guaranteed by the fundamental laws of physics. While the Micius satellite has verified the feasibility of satellite-based QKD, deploying large-scale quantum constellations remains a challenge, requiring miniaturized satellites, portable ground stations, and real-time key exchange. To this end, I will present the development and launch of a quantum microsatellite and the subsequent demonstration of real-time satellite-ground QKD with multiple small-aperture, portable ground stations. During a single satellite pass, we generated a secure key of up to 1.07 million bits. Also, a secret key, enabling one-time pad encryption of images, is created between China and South Africa at locations separated by over 12,900 kilometers on Earth. This achievement represents a critical step toward a practical global quantum network. I will also present our ongoing progress in demonstrating daylight QKD, as well as the developments of a low-Earth-orbit satellite constellation prototype and a high-Earth-orbit quantum satellite.

A coherent-state point-to-multipoint protocol is proposed to simultaneously support multiple independent quantum key distribution links between a single transmitter and massive receivers. Every prepared coherent state is measured by all receivers to generate raw keys, then processed with a secure and high-efficient key distillation method to remove the correlations between different links. The simulation results show that it can achieve remarkably high key rates even with a hundred of access points. Further, a proof-of-principle experiment with one network node and four end users has been demonstrated, where the average secret key rate of 4.1 Mbps between the transmitter and each one receiver is achieved, resulting in two orders-of-magnitude higher than previous networks. This scheme is a promising step towards a high-rate multi-user solution in a scalable quantum secure network.

Satellite-based quantum key distribution (QKD) is crucial for establishing global quantum networks, while current implementations are restricted to low-Earth-orbit satellites and nighttime operations. Geosynchronous-Earth-orbit (GEO) satellites present a compelling alternative, offering continuous availability and wide-area coverage. The primary obstacles are the substantial link loss inherent to GEO distances and high daytime ambient noise, which severely degrade the signal-to-noise ratio and hinder secure key generation. To address the challenge of daytime ambient noise, we implemented a multi-faceted filtering strategy across spatial, spectral, and temporal domains. Notably, an additional background reduction of approximately 5.2 dB was achieved using the 854.45 nm Fraunhofer line for spectral noise suppression. Simultaneously, we employed deep-learning-based adaptive optics, improving single-mode fiber coupling efficiency by approximately 1.4∼5.2 dB. We then experimentally validated all-day QKD over a metropolitan 7-km free-space channel, demonstrating continuous QKD operation throughout the day with maximum tolerable channel loss exceeding 62 dB. This represents an improvement of over one order of magnitude and surpasses the projected daytime loss budget for GEO satellite links. These results signify a major advancement towards practical, globally accessible quantum communication via GEO satellites.

Satellite-based quantum key distribution (QKD) holds the potential to establish global quantum communication networks. While satellite QKD has been extensively demonstrated using polarization encoding, time-bin encoding offers distinct advantages, such as simplifying polarization-maintaining telescope designs and being insensitive to satellite-ground relative motion. In this work, we developed a high-speed 625-MHz QKD light source using a robust Sagnac-interferometer-based modulation scheme and subsequently demonstrated time-bin QKD over a 7 km urban terrestrial free-space channel. This experiment successfully operated over a channel traversing an equivalent atmospheric thickness and loss exceeding that of typical satellite-to-ground links, achieving a low quantum bit error rate of 0.87% and a secure key rate of 134 bps@51.4 dB. Furthermore, by using a half-wave plate to simulate the polarization basis rotation inherent in such links, we verified the robustness of time-bin encoding for satellite scenarios. The results validate time-bin encoding as a compelling alternative and lay the technical foundation for future satellite QKD applications.

We report a 16QAM-modulated continuous-variable quantum key distribution system employing semidefinite programming to guarantee composable security, achieving a record-breaking secret key rate of 18.93 Mb/s over a 25 km fiber channel. Our system offers a performance advantage of more than one order of magnitude compared to previous continuous-variable quantum key distribution systems, while maintaining low complexity and being cost-effective.

Qubit-based synchronization offers a novel approach for quantum key distribution (QKD), simplifying system architecture and reducing implementation costs by leveraging the exchanged qubits. However, the performance of such schemes hinges on accumulating sufficient qubit events, rendering them vulnerable to local clock drift—particularly in high-channel-loss scenarios. This study investigates the impact of frequency instability in non-ideal oscillators, emphasizing clock drift-induced deterioration on QKD performance in these challenging, lossy conditions. We develop a computational model to quantify the secure key rate of QKD systems as a function of clock frequency stability. Through simulations and experimental validation with two distinct clock configurations, we demonstrate that oscillator stability becomes a key bottleneck in high-loss scenarios. By integrating target frequency scanning and clock offset recovery method, we verify our model via Monte Carlo simulations. Experimental validation confirms these findings, demonstrating a secure key rate of 0.37 bps at 67 dB channel loss—empirically validating the trade-off relationship among clock frequency stability, channel loss and acquisition time.

Quantum key distribution (QKD) based on the fundamental laws of quantum physics can allow the distribution of secure keys between distant users. However, the imperfections in realistic devices may lead to potential security risks, which must be accurately characterized and considered in practical security analysis. High-speed optical modulators, being as one of the core components of practical QKD systems, can be used to prepare the required quantum states. Here, we find that optical modulators based on LiNbO3, including phase modulators and intensity modulators, are vulnerable to photorefractive effect caused by external light injection. By changing the power of external light, eavesdroppers can control the intensities of the prepared states, posing a potential threat to the security of QKD. We have experimentally demonstrated the influence of light injection on LiNbO3-based optical modulators and analyzed the security risks caused by the potential green light injection attack, along with the corresponding countermeasures.