Fast Adaptive Optics for High-Dimensional Quantum Communications in Turbulent Channels

TL;DR

This paper demonstrates that high-speed adaptive optics can significantly improve the performance of high-dimensional quantum key distribution over turbulent free-space channels, enabling secure long-distance quantum communication.

Contribution

It introduces a real-time adaptive optics system that reduces wavefront distortions and crosstalk, enhancing high-dimensional QKD in turbulent atmospheric conditions.

Findings

Improved coupling efficiency of Gaussian modes through turbulence.

Significant reduction in spatial mode crosstalk.

Lowered quantum dit error rate enabling secure high-dimensional QKD.

Abstract

Quantum Key Distribution (QKD) promises a provably secure method to transmit information from one party to another. Free-space QKD allows for this information to be sent over great distances and in places where fibre-based communications cannot be implemented, such as ground-satellite. The primary limiting factor for free-space links is the effect of atmospheric turbulence, which can result in significant error rates and increased losses in QKD channels. Here, we employ the use of a high-speed Adaptive Optics (AO) system to make real-time corrections to the wavefront distortions on spatial modes that are used for high-dimensional QKD in our turbulent channel. First, we demonstrate the effectiveness of the AO system in improving the coupling efficiency of a Gaussian mode that has propagated through turbulence. Through process tomography, we show that our system is capable of significantly reducing the crosstalk of spatial modes in the channel. Finally, we show that employing AO reduces the quantum dit error rate for a high-dimensional orbital angular momentum-based QKD protocol, allowing for secure communication in a channel where it would otherwise be impossible. These results are promising for establishing long-distance free-space QKD systems.