High-fidelity remote entanglement of trapped atoms mediated by time-bin photons

Sagnik Saha; Mikhail Shalaev; Jameson O’Reilly; Isabella Goetting; George Toh; Ashish Kalakuntla; Yichao Yu; Christopher Monroe

doi:10.1038/s41467-025-57557-4

Nature Communications (Mar 2025)

High-fidelity remote entanglement of trapped atoms mediated by time-bin photons

Sagnik Saha,
Mikhail Shalaev,
Jameson O’Reilly,
Isabella Goetting,
George Toh,
Ashish Kalakuntla,
Yichao Yu,
Christopher Monroe

Affiliations

Sagnik Saha: Duke Quantum Center, Departments of Electrical and Computer Engineering and Physics, Duke University
Mikhail Shalaev: Duke Quantum Center, Departments of Electrical and Computer Engineering and Physics, Duke University
Jameson O’Reilly: Duke Quantum Center, Departments of Electrical and Computer Engineering and Physics, Duke University
Isabella Goetting: Duke Quantum Center, Departments of Electrical and Computer Engineering and Physics, Duke University
George Toh: Duke Quantum Center, Departments of Electrical and Computer Engineering and Physics, Duke University
Ashish Kalakuntla: Duke Quantum Center, Departments of Electrical and Computer Engineering and Physics, Duke University
Yichao Yu: Duke Quantum Center, Departments of Electrical and Computer Engineering and Physics, Duke University
Christopher Monroe: Duke Quantum Center, Departments of Electrical and Computer Engineering and Physics, Duke University

DOI: https://doi.org/10.1038/s41467-025-57557-4
Journal volume & issue: Vol. 16, no. 1
pp. 1 – 8

Abstract

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Abstract Photonic interconnects between quantum processing nodes are likely the only way to achieve large-scale quantum computers and networks. The bottleneck in such an architecture is the interface between well-isolated quantum memories and flying photons. We establish high-fidelity entanglement between remotely separated trapped atomic qubit memories, mediated by photonic qubits stored in the timing of their pulses. Such time-bin encoding removes sensitivity to polarization errors, enables long-distance quantum communication, and is extensible to quantum memories with more than two states. Using a measurement-based error detection process and suppressing a fundamental source of error due to atomic recoil, we achieve an entanglement fidelity of 97% and show that fundamental limits due to atomic recoil still allow fidelities in excess of 99.9%.

Published in Nature Communications

ISSN: 2041-1723 (Online)
Publisher: Nature Portfolio
Country of publisher: United Kingdom
LCC subjects: Science
Website: https://www.nature.com/ncomms/

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