Abstract
Establishing secure communication links at a global scale is a major potential application of quantum information science but also extremely challenging for the underlying technology. Although milestone experiments using satellite-to-ground links and exploiting singe-photon encoding for implementing quantum key distribution have shown recently that this goal is achievable, it is still necessary to further investigate practical solutions compatible with classical optical communication systems. Here, we examine the feasibility of establishing secret keys in a satellite-to-ground downlink configuration using continuous-variable encoding, which can be implemented using standard telecommunication components certified for space environment and able to operate at high symbol rates. Considering a realistic channel model and state-of-the-art technology, and exploiting an orbit subdivision technique for mitigating fluctuations in the transmission efficiency, we find positive secret key rates for a low-Earth-orbit scenario, whereas finite-size effects can be a limiting factor for higher orbits. Our analysis determines regions of values for important experimental parameters where secret key exchange is possible and can be used as a guideline for experimental efforts in this direction.
Highlights
Quantum key distribution (QKD) exploits the fundamental principles of physics to exchange cryptographic keys between two parties
We analyze the dependence of the secret key rate on several parameters, to obtain a better insight into which parameters affect the most the overall performance
To reduce the complexity of this multiparameter analysis, we consider here the key rate that can be obtained if the instantaneous value of the transmission efficiency is known
Summary
Quantum key distribution (QKD) exploits the fundamental principles of physics to exchange cryptographic keys between two parties. The rapid evolution in QKD implementations has resulted in extending the communication range from few centimeters of the first test to several hundreds of kilometers obtained with modern technology[3,4,5,6] This evolution in ground-based implementations faces a fundamental limitation related to the attenuation of the quantum signal in optical fibers, which increases exponentially with the distance. With this scaling law, covering several thousands of kilometers, as required for the realization of an intercontinental QKD link, would be impossible even with the most advanced technology, if only repeaterless architectures are considered[7]. Despite progress in the field[13,14], the technology is still far from being applicable to intercontinental quantum communication
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