Stress-controlled zero-field spin splitting in silicon carbide

Бреев, И. Д.; Poshakinskiy, A. V.; Yakovleva, V. V.; Nagalyuk, S. S.; Мохов, Е. Н.; Hübner, René; Астахов, Г. В.; Баранов, П. Г.; Анисимов, А. Н.

doi:10.1063/5.0040936

Cited by 15 publications

(10 citation statements)

References 39 publications

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“…In an inhomogeneously broadened ensemble with a variation of the zero-field splitting 2D, the critical temperature T c also varies. We suppose that since both variations are likely to be caused by local deformations [43], so there exists a correlation…”

Section: B Temperature Inversion Of the Odmr Signalmentioning

confidence: 99%

Inverted fine structure of a 6H-SiC qubit enabling robust spin-photon interface

D.¹,

Shang²,

Poshakinskiy³

et al. 2021

Preprint

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Section: B Temperature Inversion Of the Odmr Signalmentioning

confidence: 99%

Inverted fine structure of a 6H-SiC qubit enabling robust spin-photon interface

D.¹,

Shang²,

Poshakinskiy³

et al. 2021

Preprint

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“…We will describe the optically and electrically driven quantum emitters originating from color centers ,− and the current main challenges to achieve ideal single photon emission in this material, including their emission enhancement via material nanostructuring and their spectral and charge control in electrical devices . Specifically, we will explain the role of SiC quantum emitters as spin-photon interfaces , for remote quantum entanglement, quantum gates, and quantum photonics. ,, We will also introduce novel applications and technologies in quantum sensing of the magnetic field, − electric field, − temperature, − and strain. ,− For quantum sensing applications, photonics can play a central role in enhancing the sensitivity and acquisition time of otherwise weak quantum processes and to improve integration and scalability of future devices.…”

Section: Introductionmentioning

confidence: 99%

Silicon Carbide Photonics Bridging Quantum Technology

et al. 2022

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In the last two decades, bulk, homoepitaxial, and heteroepitaxial growth of silicon carbide (SiC) has witnessed many advances, giving rise to electronic devices widely used in highpower and high-frequency applications. Recent research has revealed that SiC also exhibits unique optical properties that can be utilized for novel photonic devices. SiC is a transparent material from the UV to the infrared, possess nonlinear optical properties from the visible to the mid-infrared and it is a meta-material in the mid-infrared range. SiC fluorescence due to color centers can be associated with single photon emitters and can be used as spin qubits for quantum computation and communication networks and quantum sensing. This unique combination of excellent electronic, photonic and spintronic properties has prompted research to develop novel devices and sensors in the quantum technology domain. In this perspective, we highlight progress, current trends and prospects of SiC science and technology underpinning the development of classical and quantum photonic devices. Specifically, we lay out the main steps recently undertaken to achieve high quality photonic components, and outline some of the current challenges SiC faces to establish its relevance as a viable photonic technology. We will also focus on its unique potential to bridge the gap between classical and quantum photonics, and to technologically advance quantum sensing applications. We will finally provide an outlook on possible alternative applications where photonics, electronics, and spintronics could merge.

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“…In contrast, if the driving field is the oscillating strain , then the different extension of the electron wave function in the ground and excited states leads typically to different spin-strain interaction constants Ξ (g) ≠ Ξ (e) (15,16,27) and, therefore, to different Rabi frequencies ħ Ω R ( g,e ) = Ξ ( g,e ) ε , so that CST can be realized experimentally.…”

Section: Introductionmentioning

confidence: 99%

“…If the spin system has the same g -factor for the ground and excited states ( 26 ), then this requirement cannot be fulfilled using RF magnetic fields because normalħΩRfalse(gfalse)=normalħΩRfalse(efalse)=gμBbrf. In contrast, if the driving field is the oscillating strain ε, then the different extension of the electron wave function in the ground and excited states leads typically to different spin-strain interaction constants Ξ ( g ) ≠ Ξ ( e ) ( 15 , 16 , 27 ) and, therefore, to different Rabi frequencies normalħΩR(g,e)=Ξ(g,e)normalε, so that CST can be realized experimentally.…”

Section: Introductionmentioning

confidence: 99%