Quantum computing with defects

Weber, J. R.; Koehl, William F.; Varley, Joel B.; Janotti, Anderson; Buckley, Bob B.; Walle, Chris G. Van de; Awschalom, D. D.

doi:10.1073/pnas.1003052107

Cited by 667 publications

(604 citation statements)

References 43 publications

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“…3 These favorable properties have stimulated a search for analogous defects in materials other than diamond. 4 One obvious candidate material is silicon carbide, a compound that is closely related to diamond in structure and bonding.…”

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confidence: 99%

“…7 Recent theoretical work has identified the N C -V Si center in 4H-SiC as a promising candidate for qubit applications. 4,5 First-principles calculations and experimental measurements have also indicated that the neutral divacancy in 4H-SiC has desirable properties 8-10 (see Fig. 1): photoluminescence, angleresolved magneto-luminescence, and continuous-wave optically-detected magnetic resonance (ODMR) measurements have demonstrated room-temperature spin control, with spin-coherence properties comparable to those of the NV center in diamond.…”

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confidence: 99%

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Defects as qubits in3C−and4H−SiC

2015

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We employ hybrid density functional calculations to search for defects in different polytypes of SiC that may serve as qubits for quantum computing. We explore the divacancy in 4H-and 3C-SiC, consisting of a carbon vacancy adjacent to a silicon vacancy, and the NV center in 3C-SiC, in which the substitutional NC sits next to a Si vacancy (NC-VSi). The calculated excitation and emission energies of the divacancy in 4H-SiC are in excellent agreement with experimental data, and aid in identifying the 4 unique configurations of the divacancy with the 4 distinct zero-phonon lines observed experimentally. For 3C-SiC, we identify the paramagnetic defect that was recently shown to maintain a coherent quantum state up to room temperature as the spin-1 neutral divacancy. Finally, we show that the (NC-VSi) − center in 3C-SiC is highly promising for quantum information science, and we provide guidance for identifying this defect.

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Defects as qubits in3C−and4H−SiC

2015

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“…Finally NV centres, even if not discussed here, occupies a special place as possible fl ying qubit for remote entangling of spin qubits in solid state, due to its optical-spin polarization properties and its possible integration in quantumhybrid-spin systems (e.g., NV and magnetic single molecules). Other deep centres as NV centre in diamond and in similar wide-bandgap semiconductors, such as SiC are under investigation [18,66] ; we are witnessing either a new era of research of another NV-like centre in solid state or the establishing of novel advanced technologies in the above-mentioned fi elds.…”

Section: Discussionmentioning

confidence: 99%

“…Several studies have addressed this issue both experimentally [14,15] and theoretically [16] . Furthermore, other atom-like defects can potentially be engineered in diamond [17] and other materials [18] with similar or perhaps better properties suitable for the desired applications.…”

Section: Introductionmentioning

confidence: 99%

Frontiers in diffraction unlimited optical methods for spin manipulation, magnetic field sensing and imaging using diamond nitrogen vacancy defects

Castelletto

2012

Nanophotonics

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The nitrogen vacancy defect centre in diamond has attracted intense research interest owing to their appealing optical and electronic properties, which have laid the ground for new approaches for diffraction unlimited optical methods. In particular, the optical detected magnetic resonance of the electron spin of nitrogen vacancy centre at room temperature underpins many areas in nanophotonics, spintronics and quantum optics. This article reviews the recent development of superresolution imaging and sensing nanoscopy based on this fascinating defect centre in diamond. These breakthroughs are presently indicating a new class of nanoscale sensors of tiny magnetic and electric fi elds at room temperature, as well as emerging fl uorescent and magnetic probes for next generation nanoscopy and all-optical spin recording.

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“…1 Examples of nuclear-electron spin complexes include those formed within self-assembled semiconductor quantum dots, 2 in the vicinity of crystal defects such as the nitrogen-vacancy center in diamond, 3 the divacancy and silicon-vacancy centers in SiC, 4,5 substitutional phosphorous 6 and bismuth 7 in silicon, rare-earth ions, 8 and others. 9 Systems formed by trapped photoexcited electrons and neighboring nuclear spins in semiconductors form a subclass of spin complexes with interesting properties. For example, because these defects often change from paramagnetic to magnetically inactive once the trapped photoelectron recombines, nuclear spins in the vicinity are inherently protected against electron-spin-induced decoherence.…”

Section: Introductionmentioning

confidence: 99%

Near-band-gap photoinduced nuclear spin dynamics in semi-insulating GaAs: Hyperfine- and quadrupolar-driven relaxation

King

Reimer

et al. 2013

Phys. Rev. B

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Understanding and manipulating spin polarization and transport in the vicinity of semiconductor-hosted defects is a problem of present technological and fundamental importance. Here, we use high-field magnetic resonance to monitor the relaxation dynamics of spin-3/2 nuclei in semi-insulating GaAs. Our experiments benefit from the conditions created in the limit of low illumination intensities, where intermittent occupation of the defect site by photoexcited electrons leads to electric field gradient fluctuations and concomitant spin relaxation of the neighboring quadrupolar nuclei. We find indication of a heterogeneous distribution of polarization, governed by different classes of defects activated by either weak or strong laser excitation. Upon application of a train of light pulses of variable repetition rate and on/off ratio, we uncover an intriguing regime of mesoscale nuclear spin diffusion restricted by long-range, nonuniform electric field gradients. Given the slow time scale governing nuclear spin evolution, such optically induced polarization patterns could be exploited as a contrast mechanism to expose dark lattice defects or localized charges with nanoscale resolution.

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Quantum computing with defects

Cited by 667 publications

References 43 publications

Defects as qubits in3C−and4H−SiC

Defects as qubits in3C−and4H−SiC

Frontiers in diffraction unlimited optical methods for spin manipulation, magnetic field sensing and imaging using diamond nitrogen vacancy defects

Near-band-gap photoinduced nuclear spin dynamics in semi-insulating GaAs: Hyperfine- and quadrupolar-driven relaxation

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