Coherent control of the silicon-vacancy spin in diamond (1701.06848v1)

Abstract: Spin impurities in diamond have emerged as a promising building block in a wide range of solid-state-based quantum technologies. The negatively charged silicon-vacancy centre combines the advantages of its high-quality photonic properties with a ground-state electronic spin, which can be read out optically. However, for this spin to be operational as a quantum bit, full quantum control is essential. Here, we report the measurement of optically detected magnetic resonance and the demonstration of coherent control of a single silicon-vacancy centre spin with a microwave field. Using Ramsey interferometry, we directly measure a spin coherence time, T2*, of 115 +/- 9 ns at 3.6 K. The temperature dependence of coherence times indicates that dephasing and decay of the spin arise from single phonon-mediated excitation between orbital branches of the ground state. Our results enable the silicon-vacancy centre spin to become a controllable resource to establish spin-photon quantum interfaces.

Coherent Control of the Silicon-Vacancy Spin in Diamond: A Path to Improved Quantum Interfaces

The paper, "Coherent Control of the Silicon-Vacancy Spin in Diamond," explores the potential of the negatively charged silicon-vacancy (SiV$^-$) center in diamond as a controllable quantum resource. The authors focus on harnessing the electronic spin of the SiV$^-$ center through coherent control mechanisms, underscoring the center's suitability for integration into quantum networks and computing paradigms.

The paper begins by situating the SiV$^-$ center within the landscape of diamond-based spin impurities, such as the well-characterized nitrogen-vacancy (NV) center. While NV centers are notable for their quantum information processing applications, their limited zero-phonon line emission (approximately 4%) restricts their practicality without extensive photonic structure modifications. In stark contrast, the SiV$^-$ center emits around 80% of its photons into the zero-phonon line, offering promising optical properties characterized by spectral stability and narrow distribution in bulk diamond settings. This positions the SiV$^-$ center as an optimal candidate for distributed quantum networks, either by exploiting its orbital branches or its electronic spin.

Through this paper, the authors report the coherent control of the SiV$^-$ electronic spin utilizing a microwave field to perform optically detected magnetic resonance (ODMR). This entails tuning the microwave frequency to achieve resonance with the Zeeman splitting between electronic spin states. They achieve a significant milestone by directly measuring a spin coherence time, T$_2^*$, of 115 ± 9 ns at a cryogenic temperature (3.6 K) using Ramsey interferometry. They further find that coherence times are primarily limited by single phonon-mediated excitations between orbital branches in the ground state, a process elucidated by observing spin and orbital population decay rates across various temperatures.

The importance of this coherent control cannot be overstated. It exemplifies a critical step towards implementing spin-based quantum computing algorithms and fostering quantum interfaces that reliably couple spin states to photonic modes. The use of microwave radiation for spin control, as opposed to purely optical methods, provides a distinct advantage. It facilitates more versatile magnetic field orientations, potentially aligning the field more closely with the SiV axis for efficient cycling transitions and single-shot spin readouts.

The results have several theoretical and practical implications. Cooling the system further could significantly enhance coherence times by minimizing phonon-induced decoherence. Alternatively, engineering solutions, such as applying strain to increase the energy separation between orbital branches, could also mitigate phononic effects. Additionally, using microwaves introduces practical advantages over optical control, particularly in hybrid quantum systems where spin-photon interfaces are crucial. This method could enable the SiV$^-$ center to act as a quantum transducer, bridging optical and microwave photonic domains.

In conclusion, this paper identifies the SiV$^-$ center in diamond as a promising candidate for future advancements in quantum technology. By achieving coherent spin control, this research lays the groundwork for more integrated and efficient quantum computing systems and networks. Future work could explore avenues to enhance coherence times through material and environmental modifications, and further probe the potentials of the associated nuclear spins in quantum information applications.