金刚石中单个硅空位自旋的全光初始化、读出及相干制备

All-optical initialization, readout, and coherent preparation of single silicon-vacancy spins in diamond.

作者信息

Rogers Lachlan J, Jahnke Kay D, Metsch Mathias H, Sipahigil Alp, Binder Jan M, Teraji Tokuyuki, Sumiya Hitoshi, Isoya Junichi, Lukin Mikhail D, Hemmer Philip, Jelezko Fedor

机构信息

Institute for Quantum Optics and Center for Integrated Quantum Science and Technology (IQst), Ulm University, Ulm D-89081, Germany.

Department of Physics, Harvard University, 17 Oxford Street, Cambridge, Massachusetts 02138, USA.

出版信息

Phys Rev Lett. 2014 Dec 31;113(26):263602. doi: 10.1103/PhysRevLett.113.263602. Epub 2014 Dec 22.

DOI:10.1103/PhysRevLett.113.263602

PMID:25615330

Abstract

The silicon-vacancy (SiV-) color center in diamond has attracted attention because of its unique optical properties. It exhibits spectral stability and indistinguishability that facilitate efficient generation of photons capable of demonstrating quantum interference. Here we show optical initialization and readout of electronic spin in a single SiV- center with a spin relaxation time of T1=2.4±0.2 ms. Coherent population trapping (CPT) is used to demonstrate coherent preparation of dark superposition states with a spin coherence time of T2⋆=35±3 ns. This is fundamentally limited by orbital relaxation, and an understanding of this process opens the way to extend coherence by engineering interactions with phonons. Hyperfine structure is observed in CPT measurements with the 29Si isotope which allows access to nuclear spin. These results establish the SiV- center as a solid-state spin-photon interface.

摘要

金刚石中的硅空位（SiV-）色心因其独特的光学性质而备受关注。它具有光谱稳定性和不可区分性，这有助于高效产生能够展示量子干涉的光子。在此，我们展示了在单个SiV-色心中对电子自旋的光学初始化和读出，其自旋弛豫时间为T1 = 2.4±0.2 ms。利用相干布居囚禁（CPT）来演示具有T2⋆ = 35±3 ns自旋相干时间的暗叠加态的相干制备。这从根本上受到轨道弛豫的限制，对这一过程的理解为通过设计与声子的相互作用来延长相干性开辟了道路。在使用29Si同位素的CPT测量中观察到超精细结构，这使得能够获取核自旋。这些结果确立了SiV-色心作为固态自旋 - 光子界面的地位。

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金刚石中单个硅空位自旋的全光初始化、读出及相干制备

All-optical initialization, readout, and coherent preparation of single silicon-vacancy spins in diamond.

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