Characterization of hyperfine interaction between an NV electron spin and a first-shell<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML"><mml:mmultiscripts><mml:mi mathvariant="normal">C</mml:mi><mml:mprescripts /><mml:none /><mml:mn>13</mml:mn></mml:mmultiscripts></mml:math>nuclear spin in diamond

Rao, K.R.S. Sambasiva; Suter, Dieter

doi:10.1103/physrevb.94.060101

Cited by 33 publications

(29 citation statements)

References 30 publications

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“…From equation (5) it follows that the dipolar terms vanish if the spin density r +   ( ) r R S n observed from the point of the 13 C nucleus is highly symmetric. As pointed out previously [23], an arbitrary NV− 13 C spin system possesses symmetry C S , which means that in the specific NV-PACS having XZ plane passing through this definite 13 C nucleus and containing the NV axis, the spin density will be symmetric with respect to the change Y to -Y, resulting in the zeroing out of the matrix element T ZY in (5). We verified numerically that in the transformed hfi matrices ¢ A KL for each position of 13 C in our cluster the element T ZY (and, additionally, elements T XY =T YX , T YZ =T ZY ) was zero.…”

Section: Methods Results and Discussionsupporting

confidence: 55%

“…In the general case the matrix A KL of the tensor (2a) is non-diagonal in the NV-PACS due to the presence of non-diagonal elements in the dipole−dipole term T KL at K ≠ L. However, symmetry properties allow the zeroing out of some of them. In particular, for each NV− 13 C spin system the T KL matrix can be simplified by choosing the X axis in such a way that the XZ plane passes through the 13 C atom of the system [23]. In this specific NV− 13 C-PACS, all elements of the respective hfi matrix ¢ A KL being non-invariant with respect to the inversion of the Y coordinate are zero due to the C S symmetry of the system.…”

Section: General Consideration Of An Arbitrary Hfi-coupled Nv− 13 C Smentioning

confidence: 99%

“…In this specific NV− 13 C-PACS, all elements of the respective hfi matrix ¢ A KL being non-invariant with respect to the inversion of the Y coordinate are zero due to the C S symmetry of the system. The hfi term then takes the form [23]:…”

Section: General Consideration Of An Arbitrary Hfi-coupled Nv− 13 C Smentioning

confidence: 99%

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Non-flipping¹³C spins near an NV center in diamond: hyperfine and spatial characteristics by density functional theory simulation of the C₅₁₀[NV]H₂₅₂cluster

et al. 2018

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Single NV centers in diamond coupled by hyperfine interaction (hfi) to neighboring 13 C nuclear spins are now widely used in emerging quantum technologies as elements of quantum memory adjusted to a nitrogen-vacancy (NV) center electron spin qubit. For nuclear spins with low flip-flop rate, single shot readout was demonstrated under ambient conditions. Here we report on a systematic search for such stable NV− 13 C systems using density functional theory to simulate the hfi and spatial characteristics of all possible NV− 13 C complexes in the H-terminated cluster C 510 [NV] -H 252 hosting the NV center. Along with the expected stable 'NV-axial− 13 C' systems wherein the 13 C nuclear spin is located on the NV axis, we found for the first time new families of positions for the 13 C nuclear spin exhibiting negligible hfi-induced flipping rates due to near-symmetric local spin density distribution. Spatially, these positions are located in the diamond bilayer passing through the vacancy of the NV center and being perpendicular to the NV axis. Analysis of available publications showed that, apparently, some of the predicted non-axial near-stable NV− 13 C systems have already been observed experimentally. A special experiment performed on one of these systems confirmed the prediction made.

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Section: Methods Results and Discussionsupporting

confidence: 55%

Section: General Consideration Of An Arbitrary Hfi-coupled Nv− 13 C Smentioning

confidence: 99%

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Non-flipping¹³C spins near an NV center in diamond: hyperfine and spatial characteristics by density functional theory simulation of the C₅₁₀[NV]H₂₅₂cluster

et al. 2018

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“…splitting into a doublet (of the triplet due to the 14 N interaction), it results here into a quartet (Rao and Suter, 2016). This is a consequence of the different orientations of the nuclear spin quantisation axes in the different electron spin states.…”

Section: Discussionmentioning

confidence: 94%

Optical Detection of Magnetic Resonance

Suter¹

2020

Preprint

Self Cite

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Abstract. The combination of magnetic resonance with laser spectroscopy provides some interesting options for increasing the sensitivity and information content of magnetic resonance. This review covers the basic physics behind the relevant processes, such as angular momentum conservation during absorption and emission. This can be used to enhance the polarization of the spin system by orders of magnitude compared to thermal polarisation as well as for detection with sensitivities down to the level of individual spins. These fundamental principles have been used in many different fields. This review summarises some of the examples in different physical systems, including atomic and molecular systems, dielectric solids composed of rare earth and transition metal ions and semiconductors.

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“…Correspondingly, the dark state is | = + ñ m 1 I , and bright state is | = -ñ m 0, 1 I . We remark that it is possible to use the same protocol to read out 13 C rather than 14 N [13-16], given wellcharacterized hyperfine interaction strengths [46][47][48][49].…”

Section: Repetitive Readout Model and Simulationmentioning

confidence: 99%

Repetitive readout enhanced by machine learning

Liu

Chen

Liu

et al. 2020

Mach. Learn.: Sci. Technol.

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Single-shot readout is a key component for scalable quantum information processing. However, many solid-state qubits with favorable properties lack the single-shot readout capability. One solution is to use the repetitive quantum-non-demolition readout technique, where the qubit is correlated with an ancilla, which is subsequently read out. The readout fidelity is therefore limited by the back-action on the qubit from the measurement. Traditionally, a threshold method is taken, where only the total photon count is used to discriminate qubit state, discarding all the information of the back-action hidden in the time trace of repetitive readout measurement. Here we show by using machine learning (ML), one obtains higher readout fidelity by taking advantage of the time trace data. ML is able to identify when back-action happened, and correctly read out the original state. Since the information is already recorded (but usually discarded), this improvement in fidelity does not consume additional experimental time, and could be directly applied to preparation-by-measurement and quantum metrology applications involving repetitive readout. IntroductionSingle-shot readout is a key component for scalable quantum information processing [1, 2], for its close connection to state initialization and fault-tolerant quantum error correction [3]. Indeed, it is one of the main deciding factors in the selection of potential qubits. Single-shot readout has been achieved in various physical qubit systems, ranging from neutral atoms [4][5][6], to trapped ions [7], superconducting qubit [8], and solid-state defect centers [9][10][11][12][13][14][15][16]. There are however situations where a candidate qubit has favorable coherence properties, but does not naturally come with single-shot readout capabilities. Examples include Al + ions [17,18] and roomtemperature nitrogen-vacancy (NV) centers in diamond [12][13][14][15][16], where a closed optical cycle for readout is either lacking, or experimentally challenging. A solution to this problem is through repetitive quantum-nondemolition (QND) measurements [18].In the repetitive QND protocol, a controlled-NOT (CNOT) gate is applied to correlate the qubit state to an ancilla, which is subsequently read out ( figure 1(a)). If the readout operator commutes with the qubit's intrinsic Hamiltonian, in other words, if the readout is QND, one can repeat the above process multiple times to increase signal-to-noise ratio, until the desired fidelity is reached.This protocol is also known as the repetitive readout technique widely adopted in NV research at roomtemperature, where the nuclear spin state (here the 14 N or a 13 C) is repetitively read out with the help of the NV electronic spin [12,19]. In its implementations so far, the spin state was determined by comparing the total photon number collected through all the repetitive readouts with a previously established threshold ( figure 1(b)). The detected photon count numbers are thus divided into two classes, referred to as bright (dark) state of the...

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Characterization of hyperfine interaction between an NV electron spin and a first-shellC13nuclear spin in diamond

Cited by 33 publications

References 30 publications

Non-flipping¹³C spins near an NV center in diamond: hyperfine and spatial characteristics by density functional theory simulation of the C₅₁₀[NV]H₂₅₂cluster

Non-flipping¹³C spins near an NV center in diamond: hyperfine and spatial characteristics by density functional theory simulation of the C₅₁₀[NV]H₂₅₂cluster

Optical Detection of Magnetic Resonance

Repetitive readout enhanced by machine learning

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Characterization of hyperfine interaction between an NV electron spin and a first-shellC13nuclear spin in diamond

Cited by 33 publications

References 30 publications

Non-flipping13C spins near an NV center in diamond: hyperfine and spatial characteristics by density functional theory simulation of the C510[NV]H252cluster

Non-flipping13C spins near an NV center in diamond: hyperfine and spatial characteristics by density functional theory simulation of the C510[NV]H252cluster

Optical Detection of Magnetic Resonance

Repetitive readout enhanced by machine learning

Contact Info

Product

Resources

About

Non-flipping¹³C spins near an NV center in diamond: hyperfine and spatial characteristics by density functional theory simulation of the C₅₁₀[NV]H₂₅₂cluster

Non-flipping¹³C spins near an NV center in diamond: hyperfine and spatial characteristics by density functional theory simulation of the C₅₁₀[NV]H₂₅₂cluster