First principles calculation of spin-related quantities for point defect qubit research

Ivády, Viktor; Abrikosov, Igor A.; Gali, Ádám

doi:10.1038/s41524-018-0132-5

Cited by 80 publications

(61 citation statements)

References 156 publications

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“…at the postulated Hpassivated nitrogen edge, for which the calculated D value agrees with the original experimental interpretation 16 , and the analogous structures for V À N , both for reasons of exploiting the analogy to understand basic principles as well as for the possible interpretation of the ODMR experiments that reported |D| < 0.004 GHz as the calculated bulk value of −0.046 GHz may be in agreement with this to within the accuracy of the calculations 40 Figure 1a plots the calculated ZFS parameter D as a function of defect location for V À B . The one-dimensional strip geometric model used for this work is shown in Fig.…”

Section: Resultssupporting

confidence: 79%

Edge effects on optically detected magnetic resonance of vacancy defects in hexagonal boron nitride

et al. 2020

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The chemical and structural nature of defects responsible for quantum emission in hexagonal boron nitride (h-BN) remain unknown. Optically detected magnetic resonance (ODMR) measured from these defects was reported in two recent papers. In one case, the ODMR was tentatively attributed to the negatively charged boron vacancy, V À B. Here we show how the key optical and magnetic properties vary with location within the bulk and along edges of h-BN sheets for this and the negatively charged nitrogen vacancy, V À N. Sign changes of the axial zero-field interaction parameter D are predicted, as well interchange of singlet and triplet ground states. Based on the latest experimental information, we assign the observed ODMR signal to bulk V À B. The other observed ODMR has some features reminiscent of our calculations for V À N edge defects.

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Section: Resultssupporting

confidence: 79%

Edge effects on optically detected magnetic resonance of vacancy defects in hexagonal boron nitride

et al. 2020

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“…To calculate the ZPL, ZFS, and hyperfine parameters we employ density functional theory [29][30][31] (DFT). The calculations are performed by using the Vienna Ab initio Simulation Package (VASP), 32,33 which uses projector augmented wave (PAW) method 34,35 for core electrons and plane wave basis set for valence electrons.…”

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confidence: 99%

Identification of divacancy and silicon vacancy qubits in 6H-SiC

Davidsson

Ivády

Armiento

et al. 2019

Applied Physics Letters

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Point defects in semiconductors are relevant for use in quantum technologies as room temperature qubits and single photon emitters. Among suggested defects for these applications are the negatively charged silicon vacancy and the neutral divacancy in SiC. The possible nonequivalent configurations of these defects have been identified in 4H-SiC, but for 6H-SiC the work is still in progress. In this paper, we identify the different configurations of the silicon vacancy and the divacancy defects to each of the V1-V3 and the QL1-QL6 color centers in 6H-SiC, respectively. We accomplish this by comparing results from ab initio calculations with experimental measurements for zero-phonon line, hyperfine tensor, and zero-field splitting.

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“…Following the guidelines of refs. 25,61 , the basal planar size as well as the k -point grid density are optimized for all the magneto-optical parameters calculated in this study. To obtain the most accurate ground state hyperfine tensors of first neighbor 13 C and second neighbor 29 Si nuclei, the HSE06 functional was used on a PBE relaxed supercell of 704 atoms with 3 × 3 × 1 k -point sampling.…”

Section: Methodsmentioning

confidence: 99%

Stabilization of point-defect spin qubits by quantum wells

et al. 2019

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Defect-based quantum systems in wide bandgap semiconductors are strong candidates for scalable quantum-information technologies. However, these systems are often complicated by charge-state instabilities and interference by phonons, which can diminish spin-initialization fidelities and limit room-temperature operation. Here, we identify a pathway around these drawbacks by showing that an engineered quantum well can stabilize the charge state of a qubit. Using density-functional theory and experimental synchrotron X-ray diffraction studies, we construct a model for previously unattributed point defect centers in silicon carbide as a near-stacking fault axial divacancy and show how this model explains these defects’ robustness against photoionization and room temperature stability. These results provide a materials-based solution to the optical instability of color centers in semiconductors, paving the way for the development of robust single-photon sources and spin qubits.

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First principles calculation of spin-related quantities for point defect qubit research

Cited by 80 publications

References 156 publications

Edge effects on optically detected magnetic resonance of vacancy defects in hexagonal boron nitride

Edge effects on optically detected magnetic resonance of vacancy defects in hexagonal boron nitride

Identification of divacancy and silicon vacancy qubits in 6H-SiC

Stabilization of point-defect spin qubits by quantum wells

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