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Reconfigurable Hexapartite Entanglement by Spatially Multiplexed Four-Wave Mixing Processes

Kai Zhang, Wei Wang, Shengshuai Liu, Xiaozhou Pan, Jinjian Du, Yanbo Lou, Shengkai Yu, Shuchao Lv, Nicolas Treps, Claude Fabre, Jietai Jing

2020Physical Review Letters98 citationsDOI

Abstract

Multipartite entanglement serves as a vital resource for quantum information processing. Generally, its generation requires complex beam splitting processes which limit scalability. A promising trend is to integrate multiple nonlinear processes into a single device via frequency or time multiplexing. The generated states in these schemes are useful for quantum computation. However, they are confined in one or two beams and hard to be spatially separated for applications in quantum communication. Here, we experimentally demonstrate a scheme to generate spatially separated hexapartite entangled states by means of spatially multiplexing seven concurrent four-wave mixing processes. In addition, we show that the entanglement structure characterized by subsystem entanglement distribution can be modified by appropriately shaping the pump characteristics. Such reconfigurability of the entanglement structure gives the possibility to target a desired multipartite entangled state for a specific quantum communication protocol. Our results here provide a new platform for generating large scale spatially separated reconfigurable multipartite entangled beams.

Topics & Concepts

Quantum entanglementMultipartite entanglementMultipartiteMultiplexingReconfigurabilityPhysicsComputer scienceMixing (physics)W stateTopology (electrical circuits)Quantum mechanicsQuantumSquashed entanglementTelecommunicationsMathematicsCombinatoricsQuantum Information and CryptographyQuantum optics and atomic interactionsQuantum Computing Algorithms and Architecture
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