Adaptive-Optics-Enabled Quantum Communication: A Technique For Daytime Space-To-Earth Links

Previous demonstrations of free-space quantum communication in daylight have been touted as significant for the development of global-scale quantum networks. Until now, no one has carefully tuned their atmospheric channel to reproduce the daytime sky radiance and slant-path turbulence conditions as they exist between space and Earth. In this article we report a quantum communication field experiment under conditions representative of daytime downlinks from space. Higher-order adaptive optics increased quantum channel efficiencies far beyond those possible with tip-tilt correction alone while spatial filtering at the diffraction limit rejected optical noise without the need for an ultranarrow spectral filter. High signal-to-noise probabilities and low quantum-bit-error rates are demonstrated over a wide range of channel radiances and turbulence conditions associated with slant-path propagation in daytime. The benefits to satellite-based quantum key distribution are quantified and discussed.