Generation and parallel manipulation of frequency entangled qubits from a 21 GHz Silicon-On-Insulator micro-resonator

Antoine Henry; Antoine Henry; Dario Fioretto; Lorenzo Proccopio; Stéphane Montfray; Frederic Boeuf; Laurent Vivien; Eric Cassan; Carlos Ramos; Kamel Bencheikh; Isabelle Zaquine; Nadia Belabas

Conference on Lasers and Electro-Optics/Europe (CLEO/Europe 2023) and European Quantum Electronics Conference (EQEC 2023)
Technical Digest Series (Optica Publishing Group, 2023),
paper eb_3_1

Generation and parallel manipulation of frequency entangled qubits from a 21 GHz Silicon-On-Insulator micro-resonator

Antoine Henry, Dario Fioretto, Lorenzo Proccopio, Stéphane Montfray, Frederic Boeuf, Laurent Vivien, Eric Cassan, Carlos Ramos, Kamel Bencheikh, Isabelle Zaquine, and Nadia Belabas

European Quantum Electronics Conference 2023

Munich Germany
26–30 June 2023
ISBN: 979-8-3503-4599-5

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Quantum optics I (eb_3)

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A. Henry, D. Fioretto, L. Proccopio, S. Montfray, F. Boeuf, L. Vivien, E. Cassan, C. Ramos, K. Bencheikh, I. Zaquine, and N. Belabas, "Generation and parallel manipulation of frequency entangled qubits from a 21 GHz Silicon-On-Insulator micro-resonator," in Conference on Lasers and Electro-Optics/Europe (CLEO/Europe 2023) and European Quantum Electronics Conference (EQEC 2023), Technical Digest Series (Optica Publishing Group, 2023), paper eb_3_1.

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Abstract

The Silicon On Insulator (SOI) is a promising platform for the generation of correlated and entangled photon pairs, as silicon photonics inherits the precise, mature, and accurate technologies from Silicon micro-electronics and allows the large-scale production of integrated photonic chips. In particular, high-quality-factor micro-resonators are well suited for producing telecom-wavelength bi-photon frequency combs, key elements for quantum information, as telecom photons are good candidates for the future links between quantum communication nodes or quantum computers [1]. Using the frequency domain for encoding information is an elegant way to access a high-dimensional Hilbert space, in one spatial mode. Recent progress in the manipulation using electro-optics devices leveraged versatile applications [2] and Hadamard gates have been implemented with classical light [3]

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