Deep Three-Dimensional Solid-State Qubit Arrays with Long-Lived Spin Coherence

C. J. Stephen; B. L. Green; Y. N.D. Lekhai; L. Weng; P. Hill; S. Johnson; A. C. Frangeskou; P. L. Diggle; Y. C. Chen; M. J. Strain; E. Gu; M. E. Newton; J. M. Smith; P. S. Salter; G. W. Morley

Journal ArticleOPEN ACCESS

Deep Three-Dimensional Solid-State Qubit Arrays with Long-Lived Spin Coherence

Physical Review Applied (2019) 12(6)

DOI: 10.1103/PhysRevApplied.12.064005

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Abstract

Nitrogen-vacancy centers (NVCs) in diamond show promise for quantum computing, communication, and sensing. However, the best current method for entangling two NVCs requires that each one is in a separate cryostat, which is not scalable. We show that single NVCs can be laser written 6-15-μm deep inside of a diamond with spin coherence times that are an order of magnitude longer than previous laser-written NVCs and at least as long as naturally occurring NVCs. This depth is suitable for integration with solid immersion lenses or optical cavities and we present depth-dependent T2 measurements. 200 000 of these NVCs would fit into one diamond.

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Stephen, C. J., Green, B. L., Lekhai, Y. N. D., Weng, L., Hill, P., Johnson, S., … Morley, G. W. (2019). Deep Three-Dimensional Solid-State Qubit Arrays with Long-Lived Spin Coherence. Physical Review Applied, 12(6). https://doi.org/10.1103/PhysRevApplied.12.064005

Deep Three-Dimensional Solid-State Qubit Arrays with Long-Lived Spin Coherence

Abstract

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