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1. Programmable quantum emitter formation in silicon

   https://doi.org/10.1038/s41467-024-48714-2  

   Jhuria, K; Ivanov, V; Polley, D; Zhiyenbayev, Y; Liu, W; Persaud, A; Redjem, W; Qarony, W; Parajuli, P; Ji, Q; et al (May 2024, Nature Communications)

   Abstract Silicon-based quantum emitters are candidates for large-scale qubit integration due to their single-photon emission properties and potential for spin-photon interfaces with long spin coherence times. Here, we demonstrate local writing and erasing of selected light-emitting defects using femtosecond laser pulses in combination with hydrogen-based defect activation and passivation at a single center level. By choosing forming gas (N₂/H₂) during thermal annealing of carbon-implanted silicon, we can select the formation of a series of hydrogen and carbon-related quantum emitters, including T and C_icenters while passivating the more common G-centers. The C_icenter is a telecom S-band emitter with promising optical and spin properties that consists of a single interstitial carbon atom in the silicon lattice. Density functional theory calculations show that the C_icenter brightness is enhanced by several orders of magnitude in the presence of hydrogen. Fs-laser pulses locally affect the passivation or activation of quantum emitters with hydrogen for programmable formation of selected quantum emitters. 

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2. Silicon Nitride Integrated Photonics with Intrinsic Quantum Emitters

   https://doi.org/10.1364/QUANTUM.2023.QM4A.3  

   Senichev, Alexander; Martin, Zachariah O; Peana, Samuel; Yesilyurt, Omer; Matthiessen, Owen M; Sychev, Demid; Lawrie, Benjamin; Lagutchev, Alexei S; Boltasseva, Alexandra; Shalaev, Vladimir M (January 2023, Optica Publishing Group)

   We create intrinsic quantum emitters in silicon nitride, study their structure and temperature-dependent optical properties, and demonstrate monolithic integration with photonic waveguides to evaluate the potential of these single-photon sources for quantum information applications. 

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3. Quantum emitters in aluminum nitride induced by heavy ion irradiation

   https://doi.org/10.1063/5.0199647  

   Senichev, Alexander; Martin, Zachariah_O; Wang, Yongqiang; Matthiessen, Owen_M; Lagutchev, Alexei; Htoon, Han; Boltasseva, Alexandra; Shalaev, Vladimir_M (July 2024, APL Quantum)

   The integration of solid-state single-photon sources with foundry-compatible photonic platforms is crucial for practical and scalable quantum photonic applications. This study explores aluminum nitride (AlN) as a material with properties highly suitable for integrated on-chip photonics and the ability to host defect-center related single-photon emitters. We have conducted a comprehensive analysis of the creation of single-photon emitters in AlN, utilizing heavy ion irradiation and thermal annealing techniques. Subsequently, we have performed a detailed analysis of their photophysical properties. Guided by theoretical predictions, we assessed the potential of Zirconium (Zr) ions to create optically addressable spin defects and employed Krypton (Kr) ions as an alternative to target lattice defects without inducing chemical doping effects. With a 532 nm excitation wavelength, we found that single-photon emitters induced by ion irradiation were primarily associated with vacancy-type defects in the AlN lattice for both Zr and Kr ions. The density of these emitters increased with ion fluence, and there was an optimal value that resulted in a high density of emitters with low AlN background fluorescence. Under a shorter excitation wavelength of 405 nm, Zr-irradiated AlN exhibited isolated point-like emitters with fluorescence in the spectral range theoretically predicted for spin-defects. However, similar defects emitting in the same spectral range were also observed in AlN irradiated with Kr ions as well as in as-grown AlN with intrinsic defects. This result is supportive of the earlier theoretical predictions, but at the same time highlights the difficulties in identifying the sought-after quantum emitters with interesting properties related to the incorporation of Zr ions into the AlN lattice by fluorescence alone. The results of this study largely contribute to the field of creating quantum emitters in AlN by ion irradiation and direct future studies emphasizing the need for spatially localized Zr implantation and testing for specific spin properties. 

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4. Single-Photon Emitters in SiN Integrated Quantum Photonics

   https://doi.org/10.1364/QUANTUM.2022.QW4B.5  

   Senichev, Alexander; Peana, Samuel; Martin, Zachariah O.; Yesilyurt, Omer; Sychev, Demid; Lagutchev, Alexei S.; Boltasseva, Alexandra; Shalaev, Vladimir M. (January 2022, Quantum 2.0 Conference 2022 Optica Publishing Group 2022)

   We report on the generation of single-photon emitters in silicon nitride. We demonstrate monolithic integration of these quantum emitters with silicon nitride waveguides showing a room-temperature off-chip count-rate of ~10⁴counts/s and clear antibunching behavior. 

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5. A monolithic immersion metalens for imaging solid-state quantum emitters

   https://doi.org/10.1038/s41467-019-10238-5  

   Huang, Tzu-Yung; Grote, Richard R.; Mann, Sander A.; Hopper, David A.; Exarhos, Annemarie L.; Lopez, Gerald G.; Klein, Amelia R.; Garnett, Erik C.; Bassett, Lee C. (June 2019, Nature Communications)

   Abstract Quantum emitters such as the diamond nitrogen-vacancy (NV) center are the basis for a wide range of quantum technologies. However, refraction and reflections at material interfaces impede photon collection, and the emitters’ atomic scale necessitates the use of free space optical measurement setups that prevent packaging of quantum devices. To overcome these limitations, we design and fabricate a metasurface composed of nanoscale diamond pillars that acts as an immersion lens to collect and collimate the emission of an individual NV center. The metalens exhibits a numerical aperture greater than 1.0, enabling efficient fiber-coupling of quantum emitters. This flexible design will lead to the miniaturization of quantum devices in a wide range of host materials and the development of metasurfaces that shape single-photon emission for coupling to optical cavities or route photons based on their quantum state. 

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