具有亚兆赫兹线宽的纳米金刚石内部硅空位中心的强耦合自旋。

Strongly coupled spins of silicon-vacancy centers inside a nanodiamond with sub-megahertz linewidth.

作者信息

Klotz Marco, Waltrich Richard, Lettner Niklas, Agafonov Viatcheslav N, Kubanek Alexander

机构信息

Institute for Quantum Optics, Ulm University, 89081 Ulm, Germany.

GREMAN, UMR 7347 CNRS, INSA-CVL, Tours University, 37200 Tours, France.

出版信息

Nanophotonics. 2024 Mar 13;13(13):2361-2366. doi: 10.1515/nanoph-2023-0927. eCollection 2024 May.

DOI:10.1515/nanoph-2023-0927

PMID:39633660

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11501644/

Abstract

The search for long-lived quantum memories, which can be efficiently interfaced with flying qubits, is longstanding. One possible solution is to use the electron spin of a color center in diamond to mediate interaction between a long-lived nuclear spin and a photon. Realizing this in a nanodiamond furthermore facilitates the integration into photonic devices and enables the realization of hybrid quantum systems with access to quantum memories. Here, we investigated the spin environment of negatively charged silicon-vacancy centers in a nanodiamond and demonstrate strong coupling of its electron spin, while the electron spin's decoherence rate remained below 1 MHz. We furthermore demonstrate multi-spin coupling with the potential to establish registers of quantum memories in nanodiamonds.

摘要

寻找能够与飞行量子比特有效对接的长寿命量子存储器的研究由来已久。一种可能的解决方案是利用金刚石中色心的电子自旋来介导长寿命核自旋与光子之间的相互作用。在纳米金刚石中实现这一点，进一步便于集成到光子器件中，并能够实现可访问量子存储器的混合量子系统。在此，我们研究了纳米金刚石中带负电荷的硅空位中心的自旋环境，并证明了其电子自旋的强耦合，同时电子自旋的退相干率保持在1兆赫兹以下。我们还展示了多自旋耦合，有潜力在纳米金刚石中建立量子存储器寄存器。

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具有亚兆赫兹线宽的纳米金刚石内部硅空位中心的强耦合自旋。

Strongly coupled spins of silicon-vacancy centers inside a nanodiamond with sub-megahertz linewidth.

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