Quantum networking relies on entanglement distribution between distant nodes, typically realized by swapping procedures. However, entanglement swapping is a demanding task in practice, mainly because of limited effectiveness of entangled photon sources and Bell-state measurements necessary to realize the process. Here we experimentally activate a remote distribution of two-photon polarization entanglement superseding the need for initial entangled pairs and traditional Bell-state measurements. This alternative procedure is accomplished thanks to the controlled spatial indistinguishability of four independent photons in three separated nodes of the network, which enables us to perform localized product-state measurements in the central node acting as a trigger. This experiment proves that the inherent indistinguishability of identical particles supply promising standards for feasible quantum communication in multinode photonic quantum networks.
Wang Y., Hao Z.-Y., Liu Z.-H., Sun K., Xu J.-S., Li C.-F., et al. (2022). Remote entanglement distribution in a quantum network via multinode indistinguishability of photons. PHYSICAL REVIEW A, 106(3), 1-9 [10.1103/PhysRevA.106.032609].
Remote entanglement distribution in a quantum network via multinode indistinguishability of photons
Castellini A.Investigation
;Compagno G.Investigation
;Lo Franco R.Supervision
2022-09-14
Abstract
Quantum networking relies on entanglement distribution between distant nodes, typically realized by swapping procedures. However, entanglement swapping is a demanding task in practice, mainly because of limited effectiveness of entangled photon sources and Bell-state measurements necessary to realize the process. Here we experimentally activate a remote distribution of two-photon polarization entanglement superseding the need for initial entangled pairs and traditional Bell-state measurements. This alternative procedure is accomplished thanks to the controlled spatial indistinguishability of four independent photons in three separated nodes of the network, which enables us to perform localized product-state measurements in the central node acting as a trigger. This experiment proves that the inherent indistinguishability of identical particles supply promising standards for feasible quantum communication in multinode photonic quantum networks.
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2107.03999v3 arxiv Phys Rev A 106 (2022).pdf
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