All-Optical dc Nanotesla Magnetometry Using Silicon Vacancy Fine Structure in Isotopically Purified Silicon Carbide

Simin, D.; Soltamov, V. A.; Poshakinskiy, A. V.; Анисимов, А. Н.; Babunts, R. A.; Tolmachev, D. O.; Мохов, Е. Н.; Trupke, Michael; Tarasenko, S. A.; Sperlich, Andreas; Баранов, П. Г.; Dyakonov, Vladimir; Астахов, Г. В.

doi:10.1103/physrevx.6.031014

Cited by 129 publications

(187 citation statements)

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“…Thus, our methods are suitable for sub-mT dc vector magnetometry. When B 0 ∼ h2D=gμ B , the suggested methods may not be useful because of complex spectra arising due to interactions among spin sublevels [56][57][58]. At high magnetic fields, e.g., B 0 ∼ 300 mT, two transitions f 21 and f 43 are well observable at every orientation as experimentally reported [17,43].…”

Section: Resultsmentioning

confidence: 92%

Vector Magnetometry Using Silicon Vacancies in4H-SiC Under Ambient Conditions

et al. 2016

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Point defects in solids promise precise measurements of various quantities. Especially magnetic field sensing using the spin of point defects has been of great interest recently. When optical readout of spin states is used, point defects achieve optical magnetic imaging with high spatial resolution at ambient conditions. Here, we demonstrate that genuine optical vector magnetometry can be realized using the silicon vacancy in SiC, which has an uncommon S ¼ 3=2 spin. To this end, we develop and experimentally test sensing protocols based on a reference field approach combined with multifrequency spin excitation. Our work suggests that the silicon vacancy in an industry-friendly platform, SiC, has the potential for various magnetometry applications under ambient conditions.

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Section: Resultsmentioning

confidence: 92%

Vector Magnetometry Using Silicon Vacancies in4H-SiC Under Ambient Conditions

et al. 2016

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“…The V2 line in 4H -SiC [4] and the V2 and V3 lines in 6H -SiC [13] are sufficiently strong to observe their corresponding electron spin via optically detected magnetic resonance (ODMR) measurements at room temperature. In particular, it has been demonstrated that the V2 color center in 4H -SiC can be used for magnetometer [17][18][19][20] and nanoscale thermometer [21] applications and as a room-temperature maser [14].Today, it is widely accepted that V1-V3 PL lines and T V1 -T V3 electron paramagnetic resonance (EPR) signals in 4H -and 6H -SiC are related to spin-3/2 negatively charged silicon vacancies [22][23][24][25]. On the other hand, the actual microscopic configuration of these vacancy related centers is still debated.…”

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confidence: 99%

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confidence: 99%

Identification of Si-vacancy related room-temperature qubits in 4H silicon carbide

et al. 2017

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The identification of a microscopic configuration of point defects acting as quantum bits is a key step in the advance of quantum information processing and sensing. Among the numerous candidates, silicon-vacancy related centers in silicon carbide (SiC) have shown remarkable properties owing to their particular spin-3/2 ground and excited states. Although, these centers were observed decades ago, two competing models, the isolated negatively charged silicon vacancy and the complex of negatively charged silicon vacancy and neutral carbon vacancy [Phys. Rev. Lett. 115, 247602 (2015)], are still argued as an origin. By means of high-precision first-principles calculations and high-resolution electron spin resonance measurements, we here unambiguously identify the Si-vacancy related qubits in hexagonal SiC as isolated negatively charged silicon vacancies. Moreover, we identify the Si-vacancy qubit configurations that provide room-temperature optical readout. DOI: 10.1103/PhysRevB.96.161114 Point defects in solids acting as quantum bits (qubits) are a highly promising platform for quantum information processing (QIP) and nanoscale sensor applications where typically their electron spin provides the functional quantum states. There are qubits that have long electron spin coherence times [1][2][3][4][5], and some of them have been demonstrated to persist up to room temperature [1,4]. These electron spins can be optically initialized and read out [2,6-9], making them very attractive candidates for QIP and related applications [10][11][12]. Among these qubits, silicon-vacancy related defects in hexagonal polytypes of SiC, such as 4H -and 6H -SiC, have shown favorable spin properties [13,14], demonstrated even at a single defect level at room temperature [4]. Two and three different silicon-vacancy related centers were observed in 4H -and 6H -SiC, where the corresponding photoluminescence (PL) lines are denoted as V1 and V2, and V1, V2, and V3, [15,16], respectively. The V2 line in 4H -SiC [4] and the V2 and V3 lines in 6H -SiC [13] are sufficiently strong to observe their corresponding electron spin via optically detected magnetic resonance (ODMR) measurements at room temperature. In particular, it has been demonstrated that the V2 color center in 4H -SiC can be used for magnetometer [17][18][19][20] and nanoscale thermometer [21] applications and as a room-temperature maser [14].Today, it is widely accepted that V1-V3 PL lines and T V1 -T V3 electron paramagnetic resonance (EPR) signals in 4H -and 6H -SiC are related to spin-3/2 negatively charged silicon vacancies [22][23][24][25]. On the other hand, the actual microscopic configuration of these vacancy related centers is still debated. The unanswered question is whether these centers are isolated silicon vacancies [V Si difference between the two models is how the observed finite zero-field splitting (ZFS) of the ground-state spin sublevels is explained. In model I, it is assumed that the C 3v symmetric crystal field, allowing nonzero ZFS [26], is strong enough t...

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“…Недавно нами были обнаружены вакансионные спиновые центры в карбиде кремния (SiC), в которых спиновые уровни с S = 3/2 селективно заселяются под дейст-вием оптического излучения в ближнем ИК-диапазоне, совместимом с полосой прозрачности волоконной оптики и биологических систем, и предложен способ использования оптически детектируемого магнит-ного резонанса (ОДМР) для измерения магнитных и температурных полей [2][3][4][5][6][7][8][9]. Был предложен оптический квантовый термометр [8], ко-торый использовал физическое явление сильного изменения интенсив-ности фотолюминесценции (ФЛ) (photoluminescence, PL) в магнитных полях, близких к точке антипересечения спиновых подуровней центров с S = 3/2 (level anticrossing -LAC) в возбужденном состоянии, которые характеризовались сильной зависимостью расщепления тонкой структуры (zero-field splitting) от температуры [7].…”

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Оптический Квантовый Термометр С Субмикронным Разрешением, Основанный На Явлении Кросс-Релаксации Спиновых Уровней

Анисимов¹,

Бабунц²,

Музафарова³

et al. 2018

Письма В Журнал Технической Физики

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An optical quantum thermometer with a submicron spatial resolution that is based on the physical phenomenon of optical response in the system of spin centers in silicon carbide under conditions of cross-relaxation between the optically active centers in quadruplet spin state and triplet centers, where there is anomalously strong dependence of the splitting of the fine structure on temperature, has been proposed.

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All-Optical dc Nanotesla Magnetometry Using Silicon Vacancy Fine Structure in Isotopically Purified Silicon Carbide

Cited by 129 publications

References 50 publications

Vector Magnetometry Using Silicon Vacancies in4H-SiC Under Ambient Conditions

Vector Magnetometry Using Silicon Vacancies in4H-SiC Under Ambient Conditions

Identification of Si-vacancy related room-temperature qubits in 4H silicon carbide

Оптический Квантовый Термометр С Субмикронным Разрешением, Основанный На Явлении Кросс-Релаксации Спиновых Уровней

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