Predicting atmospheric turbulence for secure quantum communications in free space

Atmospheric turbulence is the main barrier to large-scale free-space quantum communication networks. Aberrations distort optical information carriers, thus limiting or preventing the possibility of establishing a secure link between two parties. For this reason, forecasting the turbulence strength w...

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Bibliographic Details
Published inarXiv.org
Main Authors Jaouni, Tareq, Scarfe, Lukas, Bouchard, Frédéric, Krenn, Mario, Heshami, Khabat, Francesco Di Colandrea, Karimi, Ebrahim
Format Paper
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 20.06.2024
Subjects
Angular momentum
Atmospheric turbulence
Communication networks
Optimization
Quantum cryptography
Recurrent neural networks
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Summary:Atmospheric turbulence is the main barrier to large-scale free-space quantum communication networks. Aberrations distort optical information carriers, thus limiting or preventing the possibility of establishing a secure link between two parties. For this reason, forecasting the turbulence strength within an optical channel is highly desirable, as it allows for knowing the optimal timing to establish a secure link in advance. Here, we train a Recurrent Neural Network, TAROCCO, to predict the turbulence strength within a free-space channel. The training is based on weather and turbulence data collected over 9 months for a 5.4 km intra-city free-space link across the City of Ottawa. The implications of accurate predictions from our network are demonstrated in a simulated high-dimensional Quantum Key Distribution protocol based on orbital angular momentum states of light across different turbulence regimes. TAROCCO will be crucial in validating a free-space channel to optimally route the key exchange for secure communications in real experimental scenarios.
ISSN:2331-8422