Sujin Suwanna scite author profile

Single photon emitters in solid-state crystals have received a lot of attention as building blocks for numerous quantum technology applications. Fluorescent defects in hexagonal boron nitride (hBN) stand out due to their high luminosity and robust operation at room temperature. The fabrication of identical emitters at pre-defined sites is still challenging, which hampers the integration of these defects in optical systems and electro-optical devices. Here, we demonstrate the localized fabrication of hBN emitter arrays by electron beam irradiation using a standard scanning electron microscope with deep sub-micron lateral precision. The emitters are created with a high yield and a reproducible spectrum peaking at 575 nm. Our measurements of optically detected magnetic resonance have not revealed any addressable spin states. Using density functional theory, we attribute the experimentally observed emission lines to carbon-related defects, which are activated by the electron beam. Our scalable approach provides a promising pathway for fabricating room temperature single photon emitters in integrated quantum devices.

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Tailoring the Emission Wavelength of Color Centers in Hexagonal Boron Nitride for Quantum Applications

Cholsuk

Suwanna

Vogl

2022

Nanomaterials

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Optical quantum technologies promise to revolutionize today’s information processing and sensors. Crucial to many quantum applications are efficient sources of pure single photons. For a quantum emitter to be used in such application, or for different quantum systems to be coupled to each other, the optical emission wavelength of the quantum emitter needs to be tailored. Here, we use density functional theory to calculate and manipulate the transition energy of fluorescent defects in the two-dimensional material hexagonal boron nitride. Our calculations feature the HSE06 functional which allows us to accurately predict the electronic band structures of 267 different defects. Moreover, using strain-tuning we can tailor the optical transition energy of suitable quantum emitters to match precisely that of quantum technology applications. We therefore not only provide a guide to make emitters for a specific application, but also have a promising pathway of tailoring quantum emitters that can couple to other solid-state qubit systems such as color centers in diamond.

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Polarization dynamics of solid-state quantum emitters

Kumar¹,

Samaner²,

Cholsuk³

et al. 2023

Preprint

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Quantum emitters in solid-state crystals have recently attracted a lot of attention due to their simple applicability in optical quantum technologies. Color centers such as fluorescent defects hosted by diamond and hexagonal boron nitride (hBN) emit single photons at room temperature and can be used for nanoscale sensing. The atomic structure of the hBN defects, however, is not yet well understood. In this work, we fabricate an array of identical hBN emitters by localized electron irradiation. This allows us to correlate the dipole orientations with the host crystal axes. The angle of excitation and emission dipoles relative to the crystal axes are also calculated using density functional theory, which reveals characteristic angles for every specific defect. Moreover, we also investigate the temporal polarization dynamics and discover a mechanism of time-dependent polarization visibility and dipole orientation of color centers in hBN and diamond. This can be traced back to the excitation of excess charges in the local crystal environment. We therefore provide a promising pathway for the identification of color centers as well as important insight into the dynamics of solid-state quantum emitters.

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Machine‐Learning Clustering Technique Applied to Powder X‐Ray Diffraction Patterns to Distinguish Compositions of ThMn₁₂‐Type Alloys

Utimula

Hunkao

Yano

et al. 2020

Advcd Theory and Sims

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A clustering technique is applied using dynamic‐time‐wrapping (DTW) analysis to X‐ray diffraction (XRD) spectrum patterns in order to identify the microscopic structures of substituents introduced into the main phase of magnetic alloys. The clustering technique is found to perform well, identifying the concentrations of the substituents with success rates of ≈90%. This level of performance is attributed to the capability of DTW processing to filter out irrelevant information such as the peak intensities (due to the uncontrollability of diffraction conditions in polycrystalline samples) and the uniform shift of peak positions (due to the thermal expansion of lattices). The established framework is not limited to the system treated in this work, but is widely applicable to systems the properties of which are to be tuned by atomic substitutions within a phase. The framework has a broader potential to predict properties such as magnetic moments, optical spectra etc.) from observed XRD patterns, by predicting such properties evaluated from predicted microscopic local structure.

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Modeling of measurement-based quantum network coding on a superconducting quantum processor

et al. 2020

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Sujin Suwanna

Localized creation of yellow single photon emitting carbon complexes in hexagonal boron nitride

Tailoring the Emission Wavelength of Color Centers in Hexagonal Boron Nitride for Quantum Applications

Polarization dynamics of solid-state quantum emitters

Machine‐Learning Clustering Technique Applied to Powder X‐Ray Diffraction Patterns to Distinguish Compositions of ThMn₁₂‐Type Alloys

Modeling of measurement-based quantum network coding on a superconducting quantum processor

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Sujin Suwanna

Localized creation of yellow single photon emitting carbon complexes in hexagonal boron nitride

Tailoring the Emission Wavelength of Color Centers in Hexagonal Boron Nitride for Quantum Applications

Polarization dynamics of solid-state quantum emitters

Machine‐Learning Clustering Technique Applied to Powder X‐Ray Diffraction Patterns to Distinguish Compositions of ThMn12‐Type Alloys

Modeling of measurement-based quantum network coding on a superconducting quantum processor

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Product

Resources

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Machine‐Learning Clustering Technique Applied to Powder X‐Ray Diffraction Patterns to Distinguish Compositions of ThMn₁₂‐Type Alloys