Tailoring Fusion-Based Photonic Quantum Computing Schemes to Quantum Emitters

Ming Lai Chan; Thomas J. Bell; Love A. Pettersson; Susan X. Chen; Patrick Yard; Anders S. Sørensen; hxb885 hxb885

doi:10.1103/PRXQuantum.6.020304

Tailoring Fusion-Based Photonic Quantum Computing Schemes to Quantum Emitters

Ming Lai Chan^*, Thomas J. Bell, Love A. Pettersson, Susan X. Chen, Patrick Yard, Anders S. Sørensen, hxb885 hxb885^*

^*Corresponding author af dette arbejde

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

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Abstract

Fusion-based quantum computation is a promising quantum computing model where small-sized photonic resource states are simultaneously entangled and measured by fusion gates. Such operations can be readily implemented with scalable photonic hardware: resource states can be deterministically generated by quantum emitters and fusions require only shallow linear-optical circuits. Here, we propose fusion-based architectures tailored to the capabilities and noise models in quantum emitters. We show that high tolerance to dominant physical error mechanisms can be achieved, with fault-tolerance thresholds of 8% for photon loss, 4% for photon distinguishability between emitters, and spin noise thresholds well above memory-induced errors for typical spin-photon interfaces. Our construction and analysis provide guidelines for the development of photonic quantum hardware targeting fault-tolerant applications with quantum emitters.

Originalsprog	Engelsk
Artikelnummer	020304
Tidsskrift	PRX Quantum
Vol/bind	6
Udgave nummer	2
Antal sider	18
ISSN	2691-3399
DOI	https://doi.org/10.1103/PRXQuantum.6.020304
Status	Udgivet - 4 apr. 2025

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Publisher Copyright:
© 2025 authors.

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10.1103/PRXQuantum.6.020304Licens: CC BY

PRXQuantum.6.020304Forlagets udgivne version, 3,31 MBLicens: CC BY

Citationsformater

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abstract = "Fusion-based quantum computation is a promising quantum computing model where small-sized photonic resource states are simultaneously entangled and measured by fusion gates. Such operations can be readily implemented with scalable photonic hardware: resource states can be deterministically generated by quantum emitters and fusions require only shallow linear-optical circuits. Here, we propose fusion-based architectures tailored to the capabilities and noise models in quantum emitters. We show that high tolerance to dominant physical error mechanisms can be achieved, with fault-tolerance thresholds of 8% for photon loss, 4% for photon distinguishability between emitters, and spin noise thresholds well above memory-induced errors for typical spin-photon interfaces. Our construction and analysis provide guidelines for the development of photonic quantum hardware targeting fault-tolerant applications with quantum emitters.",

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AU - Yard, Patrick

AU - Sørensen, Anders S.

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