Flexible Cloud/User-Centric Entanglement and Photon Pair Distribution with Synthesizable Optical Router
Fabian Laudenbach, Bernhard Schrenk, Martin Achleitner, Nemanja, Voki\'c, Dinka Milovan\v{c}ev, and Hannes H\"ubel

TL;DR
This paper introduces a reconfigurable quantum network architecture that enables flexible, dynamic distribution of entangled photon pairs among multiple users over optical networks, demonstrated with experimental results showing high-visibility entanglement and adjustable photon rates.
Contribution
The work presents a novel, flexible quantum network design utilizing spectral and spatial switching, allowing dynamic, multi-user entanglement distribution without rigid passive components.
Findings
Successfully demonstrated photon pair distribution among five users over 17 km.
Achieved high-visibility entanglement shared among three users.
Enabled simultaneous multi-user photon distribution with adjustable rates.
Abstract
The practical roll-out of quantum communication technologies in optical networks and the adoption of novel quantum applications demand the distribution of single or entangled photons. Flexibility and dynamicity are paramount for the provision of quantum resources, in order to scale with the number of users and to meet the demand of complex network architectures. We present a quantum network architecture that features this degree of reconfigurability, without being restricted to a rigid physical-layer network based on purely passive multiplexing componentry. We leverage spectral assets of photon-pair sources, from the short-wavelength band to the L-band, and agile spatial switching at a remote optical network node, in order to realize a flexible distribution map that features different flavors, reaching from cloud-centric to user-centric quantum connectivity. Photon pair distribution is…
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Taxonomy
TopicsQuantum Information and Cryptography · Quantum Mechanics and Applications · Quantum optics and atomic interactions
