Spectrally stable nitrogen-vacancy centers in diamond formed by carbon implantation into thin microstructures

Yurgens, Viktoria; Corazza, A.; Zuber, Josh A.; Gruet, M.; Kasperczyk, Mark; Shields, Brendan; Warburton, Richard J.; Fontana, Yannik; Maletinsky, Patrick

doi:10.1063/5.0126669

Cited by 4 publications

(2 citation statements)

References 45 publications

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“…All of our investigated emitters with stable PLE showed narrow linewidths below 200 MHz, which is comparable with PLE-linewidths from NV-centres in µm-thick membranes [38,39] and GeV-centres in sub-µm-thick membranes [40]. Moreover, all emitters in the ∼0.65 µmthick membrane showed linewidths below 100 MHz, which is comparable with recent studies on nanophotonicallyintegrated V − Si -centres in 4H-SiC [17,19], as well as diamond-SnV centres [41,42].…”

supporting

confidence: 61%

Spectral stability of V2-centres in sub-micron 4H-SiC membranes

Körber,

Heiler,

Hesselmeier

et al. 2023

Preprint

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Colour centres in silicon carbide emerge as a promising semiconductor quantum technology platform with excellent spin-optical coherences. However, recent efforts towards maximising the photonic efficiency via integration into nanophotonic structures proved to be challenging due to reduced spectral stabilities. Here, we provide a large-scale systematic investigation on silicon vacancy centres in thin silicon carbide membranes with thicknesses down to 0.25 μm. Our membrane fabrication process involves a combination of chemical mechanical polishing, reactive ion etching, and subsequent annealing. This leads to highly reproducible membranes with roughness values of 3–4 Å, as well as negligible surface fluorescence. We find that silicon vacancy centres show close-to lifetime limited optical linewidths with almost no signs of spectral wandering down to membrane thicknesses of ∼0.7 μm. For silicon vacancy centres in thinner membranes down to 0.25 μm, we observe spectral wandering, however, optical linewidths remain below 200 MHz, which is compatible with spin-selective excitation schemes. Our work clearly shows that silicon vacancy centres can be integrated into sub-micron silicon carbide membranes, which opens the avenue towards obtaining the necessary improvements in photon extraction efficiency based on nanophotonic structuring.

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supporting

confidence: 61%

Spectral stability of V2-centres in sub-micron 4H-SiC membranes

Körber,

Heiler,

Hesselmeier

et al. 2023

Preprint

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“…PLE experiments with solid state emitters often require regular application of optical charge-resetting pulses using off-resonant laser light. ,,, Such charge resetting pulses are usually applied at wavelengths between 510 to 532 nm to undo deionization events the emitter can undergo under resonant excitation. Importantly, such repumping perturbs the charge environment of the emitter and thus induces inhomogeneous broadening, ,, precluding the observation of lifetime-limited optical linewidths.…”

mentioning

confidence: 99%

Shallow Silicon Vacancy Centers with Lifetime-Limited Optical Linewidths in Diamond Nanostructures

Zuber,

Li,

Grimau Puigibert

et al. 2023

Nano Lett.

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Coherent Microwave, Optical, and Mechanical Quantum Control of Spin Qubits in Diamond

Orphal‐Kobin,

Torun,

Bopp

et al. 2024

Adv Quantum Tech

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Diamond has emerged as a highly promising platform for quantum network applications. Color centers in diamond fulfill the fundamental requirements for quantum nodes: they constitute optically accessible quantum systems with long‐lived spin qubits. Furthermore, they provide access to a quantum register of electronic and nuclear spin qubits and they mediate entanglement between spins and photons. All these operations require coherent control of the color center's spin state. This review provides a comprehensive overview of the state‐of‐the‐art, challenges, and prospects of such schemes, including high‐fidelity initialization, coherent manipulation, and readout of spin states. Established microwave and optical control techniques are reviewed, and moreover, emerging methods such as cavity‐mediated spin–photon interactions and mechanical control based on spin–phonon interactions are summarized. For different types of color centers, namely, nitrogen–vacancy and group‐IV color centers, distinct challenges persist that are subject of ongoing research. Beyond fundamental coherent spin qubit control techniques, advanced demonstrations in quantum network applications are outlined, for example, the integration of individual color centers for accessing (nuclear) multiqubit registers. Finally, the role of diamond spin qubits in the realization of future quantum information applications is described.

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Spectrally stable nitrogen-vacancy centers in diamond formed by carbon implantation into thin microstructures

Cited by 4 publications

References 45 publications

Spectral stability of V2-centres in sub-micron 4H-SiC membranes

Spectral stability of V2-centres in sub-micron 4H-SiC membranes

Shallow Silicon Vacancy Centers with Lifetime-Limited Optical Linewidths in Diamond Nanostructures

Coherent Microwave, Optical, and Mechanical Quantum Control of Spin Qubits in Diamond

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