Shuang Wang

Recent studies have revealed critical source-side vulnerabilities in practical quantum key distribution systems. Despite their demonstrated risks, these threats receive limited attention in both academic discussions and practical implementations. To highlight the urgency of addressing source-side vulnerabilities, we will report two widespread but overlooked loopholes: the induced-photorefractive effect and the pattern effect, including a report of the first-time system-level attack against a running MDI-QKD. Except for the attack, we will also report countermeasures against the loopholes, including a fully-passive QKD architecture resistant to encoding side-channels and a correlation-immune QKD protocol mitigating the pattern effect. These works provide essential insights and solutions for advancing the practical deployment of secure QKD systems.

The remote clock synchronization in the Quantum Key Distribution (QKD) system usually relies on the transmission of synchronous optical pulses. However, the real-time jitter in the free-space channel can lead to the loss of synchronous optical pulses and the drift of the time reference. Moreover, the non-uniform distribution of channel loss in the existing post-processing methods will reduce the encoding efficiency of the filtered keys. The traditional solutions monitor the link attenuation information through independent synchronous optical signals and actively discard the key data during high-loss periods. However, this solution requires additional hardware support and has synchronization constraints. This study proposes a synchronization scheme based on real-time automatic threshold selection. By analyzing the time drift characteristics of the synchronous detector under different link attenuation conditions, this method directly realizes the automatic screening of high-loss data. This method eliminates the dependence on real-time monitoring of synchronous optical signals and achieves the automation of threshold setting through hardware architecture optimization. This solution can improve the encoding efficiency of the free-space QKD system and its principle is applicable to synchronous systems based on protocols such as BB84. This research provides a new technical path for the design of synchronization schemes for free-space quantum communication systems.

Intensity correlations between neighboring pulses open a prevalent yet often overlooked security loophole in decoy-state quantum key distribution (QKD). As a solution, we present and experimentally demonstrate an intensity-correlation-tolerant QKD protocol that mitigates the negative effect that this phenomenon has on the secret key rate according to existing security analyses. Compared to previous approaches, our method significantly enhances the robustness against correlations, notably improving both the maximum transmission distances and the achievable secret key rates across different scenarios. By relaxing constraints on correlation parameters, our protocol enables practical devices to counter intensity correlations. We experimentally demonstrate this first practical solution that directly overcomes this security vulnerability, establish the feasibility and efficacy of our proposal, taking a major step towards loophole-free and high-performance QKD.

High-dimensional entanglement not only offers a high security level for quantum communication but also promises improved information capacity and noise resistance of the system. However, due to various constraints on different high-dimensional degrees of freedom, whether these advantages can bring improvement to the actual implementation is still not well proven. Here we present a scheme to fully utilize these advantages over long-distance noisy fiber channels. We exploit polarization and time-bin hyperentanglement to achieve high-dimensional coding, and observe significant enhancements in secure key rates and noise tolerance that surpass the capabilities of qubit systems. Moreover, we constructed a four-user high-dimensional entangled QKD network over a metropolitan-scale and demonstrated its advantages in key rate, noise resilience, and networking flexibility in complex noisy network environments. Our demonstration validates the potential of high-dimensional entanglement for quantum communications over long-distance noisy channels, paving the way for a resilient and resource-efficient quantum network.

Measurement-device-independent quantum key distribution (MDIQKD) can resist all attacks on the detection devices, but there are still some security issues related to the source side. One possible solution is to use the passive protocol to eliminate the side channels introduced by active modulators at the source. Recently, a fully passive QKD protocol was proposed that could simultaneously achieve passive encoding and passive decoy-state modulation using linear optics. In this work, we propose a fully passive MDIQKD scheme that can protect the system from both side channels of source modulators and attacks on the measurement devices, which can significantly improve the implementation security of the QKD systems. We provide a specific passive encoding strategy and a method for decoy-state analysis, followed by simulation results for the secure key rate in the asymptotic scenario. Our work offers a feasible way to improve the implementation security of QKD systems and serves as a reference for achieving passive QKD schemes using realistic devices.

Measurement-device-independent quantum key distribution (MDI-QKD) is considered one of the most promising protocols due to its high performance and security. To implement the MDI-QKD system in practice, clock synchronization is a crucial step to correctly generate the secret keys. However, as practical applications advance, the complexity and cost of synchronization have become significant challenges for the implementation of MDI-QKD. In this study, we introduce a qubit-based synchronization algorithm specifically designed for MDI-QKD. By utilizing the property of Hong-Ou-Mandel interference, we achieve clock synchronization between parties of MDI-QKD without the need for additional hardware. The cost-effectiveness and simplicity of this approach are expected to significantly facilitate the practical deployment of MDI-QKD.

High-speed quantum key distribution (QKD) systems have achieved repetition frequencies above gigahertz through advanced technologies and devices, laying an important foundation for the deployment of high-key-rate QKD system. However, these advancements may introduce unknown security loopholes into the QKD system. For an eavesdropper Eve, it is challenging to exploit these security loopholes performing the intercept-and-resend attacks due to the limited time window under the high repetition frequency. Here, we propose a muted attack that does not require intercept-and-resend operation, which is applicable to high-speed QKD systems. By exploiting the security loophole of the width discriminator on the single photon avalanche detector (SPAD), Eve can control whether Bob’s detector is capable of receiving photons from Alice, allowing her to learn nearly all the keys. Additionally, we verified through experimental tests that Eve only needs to match the period of the hacking pulse with the dead time of the SPAD and ensure that each pulse contains hundreds of photons. This study reveals the security loopholes introduced by the state-of-the-art devices in high-speed QKD systems.