Quantifying n -Photon Indistinguishability with a Cyclic Integrated Interferometer

Mathias Pont; Riccardo Albiero; Sarah E. Thomas; Nicolò Spagnolo; Francesco Ceccarelli; Giacomo Corrielli; Alexandre Brieussel; Niccolo Somaschi; Hêlio Huet; Abdelmounaim Harouri; Aristide Lemaître; Isabelle Sagnes; Nadia Belabas; Fabio Sciarrino; Roberto Osellame; Pascale Senellart; Andrea Crespi

doi:10.1103/PhysRevX.12.031033

Quantifying n -Photon Indistinguishability with a Cyclic Integrated Interferometer

Mathias Pont
, Riccardo Albiero
, Sarah E. Thomas
, Nicolò Spagnolo
, Francesco Ceccarelli
, Giacomo Corrielli
, Alexandre Brieussel
, Niccolo Somaschi
, Hêlio Huet
, Abdelmounaim Harouri
, Aristide Lemaître
, Isabelle Sagnes
, Nadia Belabas
, Fabio Sciarrino
, Roberto Osellame
, Pascale Senellart
, Andrea Crespi

Centre de Nanosciences et de Nanotechnologies
Politecnico di Milano
Ev-K2-CNR Committee
University of Rome
Quandela

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

We report on a universal method to measure the genuine indistinguishability of n photons - a crucial parameter that determines the accuracy of optical quantum computing. Our approach relies on a low-depth cyclic multiport interferometer with N=2n modes, leading to a quantum interference fringe whose visibility is a direct measurement of the genuine n-photon indistinguishability. We experimentally demonstrate this technique for an eight-mode integrated interferometer fabricated using femtosecond laser micromachining and four photons from a quantum dot single-photon source. We measure a four-photon indistinguishability up to 0.81±0.03. This value decreases as we intentionally alter the photon pairwise indistinguishability. The low-depth and low-loss multiport interferometer design provides an original path to evaluate the genuine indistinguishability of resource states of increasing photon number.

langue originale	Anglais
Numéro d'article	031033
journal	Physical Review X
Volume	12
Numéro de publication	3
Les DOIs	https://doi.org/10.1103/PhysRevX.12.031033
état	Publié - 1 juil. 2022
Modification externe	Oui

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10.1103/PhysRevX.12.031033

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Pont, M., Albiero, R., Thomas, S. E., Spagnolo, N., Ceccarelli, F., Corrielli, G., Brieussel, A., Somaschi, N., Huet, H., Harouri, A., Lemaître, A., Sagnes, I., Belabas, N., Sciarrino, F., Osellame, R., Senellart, P., & Crespi, A. (2022). Quantifying n -Photon Indistinguishability with a Cyclic Integrated Interferometer. Physical Review X, 12(3), Article 031033. https://doi.org/10.1103/PhysRevX.12.031033

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title = "Quantifying n -Photon Indistinguishability with a Cyclic Integrated Interferometer",

abstract = "We report on a universal method to measure the genuine indistinguishability of n photons - a crucial parameter that determines the accuracy of optical quantum computing. Our approach relies on a low-depth cyclic multiport interferometer with N=2n modes, leading to a quantum interference fringe whose visibility is a direct measurement of the genuine n-photon indistinguishability. We experimentally demonstrate this technique for an eight-mode integrated interferometer fabricated using femtosecond laser micromachining and four photons from a quantum dot single-photon source. We measure a four-photon indistinguishability up to 0.81±0.03. This value decreases as we intentionally alter the photon pairwise indistinguishability. The low-depth and low-loss multiport interferometer design provides an original path to evaluate the genuine indistinguishability of resource states of increasing photon number.",

author = "Mathias Pont and Riccardo Albiero and Thomas, \{Sarah E.\} and Nicol{\`o} Spagnolo and Francesco Ceccarelli and Giacomo Corrielli and Alexandre Brieussel and Niccolo Somaschi and H{\^e}lio Huet and Abdelmounaim Harouri and Aristide Lema{\^i}tre and Isabelle Sagnes and Nadia Belabas and Fabio Sciarrino and Roberto Osellame and Pascale Senellart and Andrea Crespi",

note = "Publisher Copyright: {\textcopyright} 2022 authors. Published by the American Physical Society.",

year = "2022",

month = jul,

day = "1",

doi = "10.1103/PhysRevX.12.031033",

language = "English",

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Pont, M, Albiero, R, Thomas, SE, Spagnolo, N, Ceccarelli, F, Corrielli, G, Brieussel, A, Somaschi, N, Huet, H, Harouri, A, Lemaître, A, Sagnes, I, Belabas, N, Sciarrino, F, Osellame, R, Senellart, P & Crespi, A 2022, 'Quantifying n -Photon Indistinguishability with a Cyclic Integrated Interferometer', Physical Review X, VOL. 12, Numéro 3, 031033. https://doi.org/10.1103/PhysRevX.12.031033

TY - JOUR

T1 - Quantifying n -Photon Indistinguishability with a Cyclic Integrated Interferometer

AU - Pont, Mathias

AU - Albiero, Riccardo

AU - Thomas, Sarah E.

AU - Spagnolo, Nicolò

AU - Ceccarelli, Francesco

AU - Corrielli, Giacomo

AU - Brieussel, Alexandre

AU - Somaschi, Niccolo

AU - Huet, Hêlio

AU - Harouri, Abdelmounaim

AU - Lemaître, Aristide

AU - Sagnes, Isabelle

AU - Belabas, Nadia

AU - Sciarrino, Fabio

AU - Osellame, Roberto

AU - Senellart, Pascale

AU - Crespi, Andrea

PY - 2022/7/1

Y1 - 2022/7/1

N2 - We report on a universal method to measure the genuine indistinguishability of n photons - a crucial parameter that determines the accuracy of optical quantum computing. Our approach relies on a low-depth cyclic multiport interferometer with N=2n modes, leading to a quantum interference fringe whose visibility is a direct measurement of the genuine n-photon indistinguishability. We experimentally demonstrate this technique for an eight-mode integrated interferometer fabricated using femtosecond laser micromachining and four photons from a quantum dot single-photon source. We measure a four-photon indistinguishability up to 0.81±0.03. This value decreases as we intentionally alter the photon pairwise indistinguishability. The low-depth and low-loss multiport interferometer design provides an original path to evaluate the genuine indistinguishability of resource states of increasing photon number.

AB - We report on a universal method to measure the genuine indistinguishability of n photons - a crucial parameter that determines the accuracy of optical quantum computing. Our approach relies on a low-depth cyclic multiport interferometer with N=2n modes, leading to a quantum interference fringe whose visibility is a direct measurement of the genuine n-photon indistinguishability. We experimentally demonstrate this technique for an eight-mode integrated interferometer fabricated using femtosecond laser micromachining and four photons from a quantum dot single-photon source. We measure a four-photon indistinguishability up to 0.81±0.03. This value decreases as we intentionally alter the photon pairwise indistinguishability. The low-depth and low-loss multiport interferometer design provides an original path to evaluate the genuine indistinguishability of resource states of increasing photon number.

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VL - 12

JO - Physical Review X

JF - Physical Review X

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ER -

Quantifying n -Photon Indistinguishability with a Cyclic Integrated Interferometer

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