Konstantin Kravtsov

We experimentally demonstrate a feasible experimental setup that implements the original B92 QKD protocol with strong reference pulses. The observed performance of the scheme is quite promising and allows for actual quantum key distribution, provided the corresponding theoretic foundation is developed. Our results on the latter will be provided elsewhere.

Quantum communication protocols, offering information-theoretic security, position satellite-based quantum key distribution (QKD) as a pivotal enabler for secure global communication networks. To ensure practical utility for end-users, the placement of optical ground stations (OGSs) must be strategically determined based on the topology of terrestrial quantum networks. Importantly, the site selection criteria recognize that free-space channels, unlike astronomical sites, are not optimized for such applications. Therefore, a comprehensive characterization of free-space channels in diverse environments is essential for designing and implementing a robust global quantum network. In this study, we present a measurement-based characterization of the atmospheric channel at the Abu Dhabi Quantum Optical Ground Station (ADQOGS). Two complementary experimental setups were employed: a ground-based weather station, which continuously monitors key atmospheric parameters, and a quantum acquisition and tracking system that integrates single-photon detectors, mounted on an RC telescope. These setups enable the simultaneous acquisition of classical and quantum signals, both of which are critical for assessing satellite QKD links. We report the experimental results acquired at the ADQOGS site, focusing on key atmospheric parameters impacting satellite-ground quantum communication. Specifically, we show measurements of atmospheric turbulence and background light. The results were analyzed to evaluate their impact on link availability and overall QKD performance in different scenarios. Our findings offer valuable insights for optimizing satellite-ground quantum links, enhancing link stability, and informing the design of future large-scale quantum-secure communication networks. This work contributes to the ongoing efforts toward establishing a robust global quantum communication infrastructure.

We present the Abu Dhabi Quantum Optical Ground Station (ADQOGS), a versatile optical ground station designed for diverse satellite-based quantum key distribution (QKD) missions. As the first of its kind in the Middle East, ADQOGS’s primary goal is to connect the UAE to global quantum-secured communication networks, thus overcoming the limited reach of terrestrial, fiber-based, QKD lines. The ability of the station to accommodate the reception and emission of multiwavelength optical signals promotes the diversification of space-based trusted nodes and allows a novel parallel trusted node approach to space QKD.

Quantum key distribution (QKD) via satellite links is the only currently viable solution to create quantum-backed secure communication at a global scale. To achieve intercontinental coverage with available technology one must adopt a “flying trusted node” paradigm, in which users fully trust the satellite platform. The major part of the poster will focus on our latest work where inspired by the concept of distributed secret sharing and the imminent projected launch of several QKD-equipped satellites, we proposed a parallel trusted node approach, in which key distribution is mediated by several satellites in parallel. This distributes the trust, removes single points of failure, and reduces the necessary assumptions. In addition, we discussed the versatility that an optical ground station should provide to execute such a protocol and, in general, to be fully integrated into a multi-party global quantum network. Finally, one last section of the poster will focus on how we will implement the idea of versatility and adaptability at the Abu Dhabi Quantum Optical Ground Station from a hardware perspective.