低温下金刚石中单氮空位中心电荷态的光控开关。

Optically controlled switching of the charge state of a single nitrogen-vacancy center in diamond at cryogenic temperatures.

机构信息

3. Physikalisches Institut and Stuttgart Research Center of Photonic Engineering (SCoPE), Universität Stuttgart, Pfaffenwaldring 57, Stuttgart D-70569, Germany.

出版信息

Phys Rev Lett. 2013 Apr 19;110(16):167402. doi: 10.1103/PhysRevLett.110.167402. Epub 2013 Apr 16.

DOI:10.1103/PhysRevLett.110.167402

PMID:23679637

Abstract

In this Letter, the photoinduced switching of the single nitrogen-vacancy (NV) center between two different charge states, negative (NV(-)) and neutral (NV(0)), is studied under resonant excitation at liquid helium temperature. We show that resonant conversion of NV(0) to NV(-) significantly improves spectral stability of the NV(-) defect and allows high fidelity initialization of the spin qubit. Based on density functional theory calculations a novel mechanism involving an Auger ionization of NV(-) and charge transfer of an electron from the valence band to NV(0) is discussed. This study provides further insight into the charge dynamics of the NV center, which is relevant for quantum information processing based on an NV(-) defect in diamond.

摘要

在这封信件中，研究了在液氦温度下共振激发下，单氮空位（NV）中心在两种不同电荷态之间的光诱导开关，即负（NV(-)）和中性（NV(0)）。我们表明，NV(0)到 NV(-)的共振转换显著提高了 NV(-)缺陷的光谱稳定性，并允许对自旋量子位进行高保真初始化。基于密度泛函理论计算，讨论了一种涉及 NV(-)的俄歇电离和价带中的电子向 NV(0)的电荷转移的新机制。这项研究为 NV 中心的电荷动力学提供了进一步的见解，这对于基于金刚石中的 NV(-)缺陷的量子信息处理是相关的。

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低温下金刚石中单氮空位中心电荷态的光控开关。

Optically controlled switching of the charge state of a single nitrogen-vacancy center in diamond at cryogenic temperatures.

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