Satellite-Based Entanglement Distribution using Orbital Angular Momentum of Light

Orbital angular momentum (OAM) of light has been considered as a useful degree of freedom for high-capacity quantum communications. However, the practical usage of OAM within the atmospheric channel is known to be limited by turbulence-induced decoherence effects. In this work, we study the feasibility of utilizing the OAM of light in satellite-based entanglement distribution. In order to determine whether OAM entanglement could be distributed within the context of satellite-based quantum communications, we study the quantum state evolution of a pair of OAM-entangled photons that traverse independent and identically distributed satellite-to-ground atmospheric channels. Our calculations indicate the performance levels that any post-selection, or distillation, scheme must have in order to achieve useful OAM entanglement distribution via a low-Earth-orbit satellite.