Integrated photonic source of Gottesman–Kitaev–Preskill qubits

Larsen, Mikkel V.; Bourassa, J. Eli; Kocsis, Sacha; Tasker, Joel F.; Chadwick, Rob; González-Arciniegas, Carlos; Hastrup, Jacob; Lopetegui-González, C E; Miatto, Filippo M.; Motamedi, A.; Noro, Ryosuke; Roeland, Ganaël; Baby, R.; Chen, Haiyan; Contu, Pietro; Luch, Ilaria Di; Drago, Christian; Giesbrecht, M; Grainge, T.; Krasnokutska, Inna; Menotti, M.; Morrison, Blair; Puviraj, C; Shad, Kimia Rezaei; Hussain, Babar; McMahon, Joanne; Ortmann, J. Elliott; Collins, Matthew J.; Ma, Chensheng; Phillips, D. S.; Seymour, Michael H.; Tang, Q. Y.; Yang, Bo; Vernon, Z.; Alexander, Rafael N.; Mahler, Dylan H.

doi:10.1038/s41586-025-09044-5

articleNatureJun 4, 2025HYBRID OA

Integrated photonic source of Gottesman–Kitaev–Preskill qubits

MVMikkel V. Larsen JEJ. Eli Bourassa SKSacha Kocsis JFJoel F. Tasker RCRob Chadwick

Xanadu Quantum Technologies (Canada)

PubMed

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Abstract

Building a useful photonic quantum computer requires robust techniques to synthesize optical states that can encode qubits. Gottesman–Kitaev–Preskill (GKP) states1 offer one of the most attractive classes of such qubit encodings, as they enable the implementation of universal gate sets with straightforward, deterministic and room temperature-compatible Gaussian operations2. Existing pioneering demonstrations generating optical GKP states3 and other complex non-Gaussian states4–11 have relied on free-space optical components, hindering the scaling eventually required for a utility-scale system. Here we use an ultra-low-loss integrated photonic chip fabricated on a customized multilayer silicon nitride 300-mm…

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Topics & keywords

Topics

Keywords

Qubit
Photonics
Physics
Quantum
Quantum mechanics

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Funding

NI
National Institute of Standards and Technology