Litcius/Paper detail

Efficient reversible entanglement transfer between light and quantum memories

Mingtao Cao, Félix Hoffet, Shuwei Qiu, Alexandra S. Sheremet, Julien Laurat

2020Optica74 citationsDOIOpen Access PDF

Abstract

Reversible entanglement transfer between light and matter is a crucial requisite for the ongoing developments of quantum information technologies. Quantum networks and their envisioned applications, e.g., secure communications beyond direct transmission, distributed quantum computing, or enhanced sensing, rely on entanglement distribution between nodes. Although entanglement transfer has been demonstrated, a current roadblock is the limited efficiency of this process that can compromise the scalability of multi-step architectures. Here we demonstrate the efficient transfer of heralded single-photon entanglement into and out of two quantum memories based on large ensembles of cold cesium atoms. We achieve an overall storage-and-retrieval efficiency of 85% together with a preserved suppression of the two-photon component of about 10% of the value for a coherent state. Our work constitutes an important capability that is needed toward large scale networks and increased functionality.

Topics & Concepts

Quantum entanglementQuantum networkPhysicsQuantumQuantum sensorQuantum mechanicsScalabilityQuantum information scienceQuantum informationAmplitude damping channelComputer scienceQuantum technologyQuantum channelQuantum capacityTransfer (computing)Topology (electrical circuits)Multipartite entanglementScale (ratio)Quantum key distributionQuantum teleportationQuantum information processingValue (mathematics)Component (thermodynamics)Quantum metrologyQuantum computerQuantum Information and CryptographyQuantum optics and atomic interactionsCold Atom Physics and Bose-Einstein Condensates