Abstract
Recent experimental breakthroughs in satellite quantum communications have opened up the possibility of creating a global quantum internet using satellite links. This approach appears to be particularly viable in the near term, due to the lower attenuation of optical signals from satellite to ground, and due to the currently short coherence times of quantum memories. The latter prevents ground-based entanglement distribution using atmospheric or optical-fiber links at high rates over long distances. In this work, we propose a global-scale quantum internet consisting of a constellation of orbiting satellites that provides a continuous, on-demand entanglement distribution service to ground stations. The satellites can also function as untrusted nodes for the purpose of long-distance quantum-key distribution. We develop a technique for determining optimal satellite configurations with continuous coverage that balances both the total number of satellites and entanglement-distribution rates. Using this technique, we determine various optimal satellite configurations for a polar-orbit constellation, and we analyze the resulting satellite-to-ground loss and achievable entanglement-distribution rates for multiple ground station configurations. We also provide a comparison between these entanglement-distribution rates and the rates of ground-based quantum repeater schemes. Overall, our work provides the theoretical tools and the experimental guidance needed to make a satellite-based global quantum internet a reality.
Highlights
One of the most remarkable applications of quantum mechanics is the ability to perform secure communication via quantum-key distribution (QKD)[1,2,3,4]
With several metropolitan-scale QKD systems already in place[8,9,10,11,12,13,14,15], and with the development of quantum computers proceeding at a steady pace[16,17,18], the time is right to begin transitioning to a global quantum communications network before full-scale quantum computers render current communication systems defenseless[19,20,21]
It is well known that optical signals transmitted through either the atmosphere or optical fibers undergo an exponential decrease in the transmission success probability with distance[36,37]
Summary
One of the most remarkable applications of quantum mechanics is the ability to perform secure communication via quantum-key distribution (QKD)[1,2,3,4]. All of the aforementioned tasks make use of shared entanglement between distant locations on the earth, which is typically distributed using single-photonic qubits sent through either the atmosphere or optical fibers. These schemes require reliable single-photon sources, quantum memories with high coherence times, and quantum gate operations with low error. Experimental demonstrations performed so far have been limited[47,48,49] and do not scale to the distances needed to realize a global-scale quantum internet
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