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Research PaperResearchia:202607.01014

Efficient entanglement of three remote single-atom quantum-network nodes

Matthias Seubert

Abstract

Entanglement distributed over a set of individually addressable qubit nodes is the enabling resource for a plethora of applications ranging from tests of quantum physics to secure and modular quantum information networks. Entanglement between two memory qubits has been realized on various platforms, but extension to more nodes remains rare and formidably challenging. The principal bottleneck is the efficiency of the light-matter interfaces connecting the qubit nodes to their communication channe...

Submitted: July 1, 2026Subjects: Quantum Physics; Quantum Computing

Description / Details

Entanglement distributed over a set of individually addressable qubit nodes is the enabling resource for a plethora of applications ranging from tests of quantum physics to secure and modular quantum information networks. Entanglement between two memory qubits has been realized on various platforms, but extension to more nodes remains rare and formidably challenging. The principal bottleneck is the efficiency of the light-matter interfaces connecting the qubit nodes to their communication channels. Here, we efficiently generate, distribute and store a three-qubit entangled state across three independent laboratories containing single atoms coupled to optical resonators. We sequentially entangle the atoms pairwise, two by heralded photonic entanglement swapping and two by heralded state transfer. We reach a three-qubit entanglement fidelity of 77(1)% and an entanglement lifetime above 200us. The observed qubit correlations violate Mermin's inequality while closing the detection loophole. Our three-qubit entanglement-generation efficiency is 0.16%. This unprecedented efficiency of our scheme establishes a clear route towards multi-node quantum networks.


Source: arXiv:2606.32006v1 - http://arxiv.org/abs/2606.32006v1 PDF: https://arxiv.org/pdf/2606.32006v1 Original Link: http://arxiv.org/abs/2606.32006v1

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Submission Info
Date:
Jul 1, 2026
Topic:
Quantum Computing
Area:
Quantum Physics
Comments:
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