Bulletin of the American Physical Society
APS March Meeting 2021
Volume 66, Number 1
Monday–Friday, March 15–19, 2021; Virtual; Time Zone: Central Daylight Time, USA
Session M29: Semiconductor Qubits - Novel Spin Qubit Materials and Technologies I
11:30 AM–2:30 PM,
Wednesday, March 17, 2021
Sponsoring
Unit:
DQI
Chair: Daniel Keith
Abstract: M29.00005 : Single artificial atoms in silicon emitting at telecom wavelengths
12:18 PM–12:30 PM
Live
Presenter:
Alrik Durand
(Laboratoire Charles Coulomb - Montpellier)
Authors:
Alrik Durand
(Laboratoire Charles Coulomb - Montpellier)
Walid Redjem
(Laboratoire Charles Coulomb - Montpellier)
Tobias Herzig
(Division of Applied Quantum Systems, Felix-Bloch Institute for Solid-State Physics, University Leipzig)
Abdennacer Benali
(IM2NP, Marseille)
Sebastien Pezzagna
(Division of Applied Quantum Systems, Felix-Bloch Institute for Solid-State Physics, University Leipzig)
Jan Meijer
(Division of Applied Quantum Systems, Felix-Bloch Institute for Solid-State Physics, University Leipzig)
Andrej Kuznetsov
(Department of Physics, University of Oslo)
Hai Son Nguyen
(Institut des Nanotechnologies de Lyon)
Sebastien Cueff
(Institut des Nanotechnologies de Lyon)
Jean-Michel Gerard
(Department of Physics, IRIG, CEA)
Isabelle Robert-Philip
(Laboratoire Charles Coulomb - Montpellier)
Bernard Gil
(Laboratoire Charles Coulomb - Montpellier)
Damien Caliste
(Department of Physics, IRIG, CEA)
Pascal Pochet
(Department of Physics, IRIG, CEA)
Marco Abbarchi
(IM2NP, Marseille)
Vincent Jacques
(Laboratoire Charles Coulomb - Montpellier)
Anaïs Dréau
(Laboratoire Charles Coulomb - Montpellier)
Guillaume Cassabois
(Laboratoire Charles Coulomb - Montpellier)
Given its unrivaled potential of integration and scalability, silicon is likely to become a key platform for large-scale quantum technologies. Individual electron-encoded artificial atoms either formed by impurities or quantum dots have emerged as a promising solution for silicon-based integrated quantum circuits. However, single qubits featuring an optical interface needed for large-distance exchange of information have not yet been isolated in such a prevailing semiconductor. In our recent work [1], we show the isolation of single optically-active point defects in a commercial silicon-on-insulator wafer implanted with carbon atoms. These artificial atoms exhibit a bright, linearly polarized single-photon emission at telecom wavelengths suitable for long-distance propagation in optical fibers. Our results demonstrate that despite its small bandgap (1.1 eV) a priori unfavorable towards such observation, silicon can accommodate point defects optically isolable at single scale, like in wide-bandgap semiconductors. This work opens numerous perspectives for silicon-based quantum technologies, from integrated quantum photonics to quantum communications and metrology.
[1] Redjem*, Durand* et al., arXiv:2001.02136 (2020)
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