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Cavity-enhanced single artificial atoms in silicon

The authors demonstrate a cavity enhancement of single artificial atoms at telecommunication wavelengths in silicon by coupling them to highly optimized photonic crystal cavities, showing intensity enhancement and highly pure single-photon emission.

Valeria Saggio
Carlos Errando-Herranz
Dirk Englund
ResearchOpen Access21 Jun 2024
Nature Communications

Volume: 15, P: 1-6
Individually addressable and spectrally programmable artificial atoms in silicon photonics

Realising integrated photonic circuits containing isolated telecommunications-wavelength artificial atom single photon emitters is an outstanding challenge in quantum technologies. Here, the authors demonstrate how to embed optically tunable G-centers in silicon-on-insulator integrated circuits.

Mihika Prabhu
Carlos Errando-Herranz
Dirk Englund
ResearchOpen Access25 Apr 2023
Nature Communications

Volume: 14, P: 1-7
Spectral tuning and nanoscale localization of single color centers in silicon via controllable strain

Precise control of color centers in silicon can enable scalable quantum photonic networks. Here, the authors demonstrate emission wavelength tuning and nanoscale vertical localization of individual quantum emitters within photonic integrated circuits via localized electromechanical strain.

Alessandro Buzzi
Camille Papon
Dirk Englund
ResearchOpen Access03 Oct 2025
Nature Communications

Volume: 16, P: 1-10
Tunable quantum emitters on large-scale foundry silicon photonics

Integrating tunable quantum emitters with commercial photonic circuits is promising for quantum information applications but remains a challenge. Here the authors report integration of InAs/InP microchiplets containing quantum dot single photon emitters into a large-scale foundry silicon platform.

Hugo Larocque
Mustafa Atabey Buyukkaya
Dirk Englund
ResearchOpen Access10 Jul 2024
Nature Communications

Volume: 15, P: 1-9
Three-dimensional printing of silica glass with sub-micrometer resolution

Silica glass is a high-performance material used in most branches of society from glassware and windows to optical lenses and fibers. Here, we develop a sintering-free method for 3D printing silica glass with sub-micrometer resolution and successfully demonstrate an optical microtoroid resonator.

Po-Han Huang
Miku Laakso
Frank Niklaus
ResearchOpen Access07 Jun 2023
Nature Communications

Volume: 14, P: 1-10
Heterogeneous integration of spin–photon interfaces with a CMOS platform

A modular quantum system-on-chip architecture integrates thousands of individually addressable spin qubits in two-dimensional quantum microchiplet arrays into an integrated circuit designed for cryogenic control, supporting full connectivity for quantum memory arrays across spin–photon channels.

Linsen Li
Lorenzo De Santis
Dirk Englund
Research29 May 2024
Nature

Volume: 630, P: 70-76
Reconfigurable photonics with on-chip single-photon detectors

Integrated photonics are promising to scale up quantum optics. Here the authors combine low-power microelectromechanical control and superconducting single-photon detectors on the same chip and demonstrate routing, high-dynamic-range detection, and power stabilization.

Samuel Gyger
Julien Zichi
Carlos Errando-Herranz
ResearchOpen Access03 Mar 2021
Nature Communications

Volume: 12, P: 1-8
Correction: Integrated silicon photonic MEMS

Niels Quack
Alain Yuji Takabayashi
Wim Bogaerts
Amendments and CorrectionsOpen Access24 Jan 2024
Microsystems & Nanoengineering

Volume: 10, P: 1
Integrated silicon photonic MEMS

Niels Quack
Alain Yuji Takabayashi
Wim Bogaerts
ResearchOpen Access20 Mar 2023
Microsystems & Nanoengineering

Volume: 9, P: 1-22

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