Satellite-based Quantum Key Distribution over Atmospheric Channels: Reviews and Research Challenges

The ultra-secure quantum network leverages quantum mechanical concepts to deliver unsurpassed data transfer security. In principle, the well-known quantum key distribution (QKD) achieves unconditional security, which raises concerns about the trustworthiness of 6G wireless systems. The long-distance satellite-to-ground evolving quantum network distributes keys that are ubiquitous to the node on the ground through low-orbit satellites. As the secret key sequence is encoded into quantum states, it is sent through the atmosphere via a quantum channel. However, achieving high-quality quantum communication requires more effort in deployment ranges, physical layer transmission, and security. In this paper, we first study the quantum states and channel properties for satellite-based QKD networks and long-range quantum state transfer (QST). Moreover, we highlight some challenges, such as transmissivity statistics, estimation of channel parameters and attack resilience, quantum state transfer for satellite-based QKD networks, and wavepacket shaping techniques over atmospheric channels. Furthermore, we underline two open challenges that consider the QST to the atmospheric transmission and wavepacket shaping techniques via atmospheric channels in order to encourage further research toward the next generation of satellite-based QKD networks.