Broad Diversity of Near-Infrared Single-Photon Emitters in Silicon

A. Durand; Y. Baron; W. Redjem; T. Herzig; A. Benali; S. Pezzagna; J. Meijer; A. Yu Kuznetsov; J. M. Gérard; I. Robert-Philip; M. Abbarchi; V. Jacques; G. Cassabois; A. Dréau

doi:10.1103/PhysRevLett.126.083602

Broad Diversity of Near-Infrared Single-Photon Emitters in Silicon

A. Durand
, Y. Baron
, W. Redjem
, T. Herzig
, A. Benali
, S. Pezzagna
, J. Meijer
, A. Yu Kuznetsov
, J. M. Gérard
, I. Robert-Philip
, M. Abbarchi
, V. Jacques
, G. Cassabois
, A. Dréau

Nanoscale Science and Engineering

University at Albany

Université de Montpellier
Leipzig University
Université de Provence
University of Oslo
Université Grenoble Alpes

Research output: Contribution to journal › Article › peer-review

101 Scopus citations

Abstract

We report the detection of individual emitters in silicon belonging to seven different families of optically active point defects. These fluorescent centers are created by carbon implantation of a commercial silicon-on-insulator wafer usually employed for integrated photonics. Single photon emission is demonstrated over the 1.1-1.55 μm range, spanning the O and C telecom bands. We analyze their photoluminescence spectra, dipolar emissions, and optical relaxation dynamics at 10 K. For a specific family, we show a constant emission intensity at saturation from 10 K to temperatures well above the 77 K liquid nitrogen temperature. Given the advanced control over nanofabrication and integration in silicon, these individual artificial atoms are promising systems to investigate for Si-based quantum technologies.

Original language	English
Article number	083602
Journal	Physical Review Letters
Volume	126
Issue number	8
DOIs	https://doi.org/10.1103/PhysRevLett.126.083602
State	Published - Feb 22 2021

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10.1103/PhysRevLett.126.083602

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title = "Broad Diversity of Near-Infrared Single-Photon Emitters in Silicon",

abstract = "We report the detection of individual emitters in silicon belonging to seven different families of optically active point defects. These fluorescent centers are created by carbon implantation of a commercial silicon-on-insulator wafer usually employed for integrated photonics. Single photon emission is demonstrated over the 1.1-1.55 μm range, spanning the O and C telecom bands. We analyze their photoluminescence spectra, dipolar emissions, and optical relaxation dynamics at 10 K. For a specific family, we show a constant emission intensity at saturation from 10 K to temperatures well above the 77 K liquid nitrogen temperature. Given the advanced control over nanofabrication and integration in silicon, these individual artificial atoms are promising systems to investigate for Si-based quantum technologies.",

author = "A. Durand and Y. Baron and W. Redjem and T. Herzig and A. Benali and S. Pezzagna and J. Meijer and Kuznetsov, \{A. Yu\} and G{\'e}rard, \{J. M.\} and I. Robert-Philip and M. Abbarchi and V. Jacques and G. Cassabois and A. Dr{\'e}au",

note = "Publisher Copyright: {\textcopyright} 2021 American Physical Society.",

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month = feb,

day = "22",

doi = "10.1103/PhysRevLett.126.083602",

language = "English",

volume = "126",

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TY - JOUR

T1 - Broad Diversity of Near-Infrared Single-Photon Emitters in Silicon

AU - Durand, A.

AU - Baron, Y.

AU - Redjem, W.

AU - Herzig, T.

AU - Benali, A.

AU - Pezzagna, S.

AU - Meijer, J.

AU - Kuznetsov, A. Yu

AU - Gérard, J. M.

AU - Robert-Philip, I.

AU - Abbarchi, M.

AU - Jacques, V.

AU - Cassabois, G.

AU - Dréau, A.

PY - 2021/2/22

Y1 - 2021/2/22

N2 - We report the detection of individual emitters in silicon belonging to seven different families of optically active point defects. These fluorescent centers are created by carbon implantation of a commercial silicon-on-insulator wafer usually employed for integrated photonics. Single photon emission is demonstrated over the 1.1-1.55 μm range, spanning the O and C telecom bands. We analyze their photoluminescence spectra, dipolar emissions, and optical relaxation dynamics at 10 K. For a specific family, we show a constant emission intensity at saturation from 10 K to temperatures well above the 77 K liquid nitrogen temperature. Given the advanced control over nanofabrication and integration in silicon, these individual artificial atoms are promising systems to investigate for Si-based quantum technologies.

AB - We report the detection of individual emitters in silicon belonging to seven different families of optically active point defects. These fluorescent centers are created by carbon implantation of a commercial silicon-on-insulator wafer usually employed for integrated photonics. Single photon emission is demonstrated over the 1.1-1.55 μm range, spanning the O and C telecom bands. We analyze their photoluminescence spectra, dipolar emissions, and optical relaxation dynamics at 10 K. For a specific family, we show a constant emission intensity at saturation from 10 K to temperatures well above the 77 K liquid nitrogen temperature. Given the advanced control over nanofabrication and integration in silicon, these individual artificial atoms are promising systems to investigate for Si-based quantum technologies.

UR - https://www.scopus.com/pages/publications/85102413722

U2 - 10.1103/PhysRevLett.126.083602

DO - 10.1103/PhysRevLett.126.083602

M3 - Article

C2 - 33709758

SN - 0031-9007

VL - 126

JO - Physical Review Letters

JF - Physical Review Letters

IS - 8

M1 - 083602

ER -

Broad Diversity of Near-Infrared Single-Photon Emitters in Silicon

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