Sensing Coherent Nuclear Spin Dynamics with an Ensemble of Paramagnetic Nitrogen Spins

PRX Quantum Pub Date : 2024-05-14 DOI:10.1103/prxquantum.5.020334

R.M. Goldblatt, A.M. Martin, A.A. Wood

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Abstract

The unpolarized spin environment surrounding a central spin qubit is typically considered as an incoherent source of dephasing, however, precise characterization and control of the spin bath can yield a resource for storing and sensing with quantum states. In this work, we use nitrogen-vacancy (NV) centers in diamond to measure the coherence of optically dark paramagnetic nitrogen defects (P1 centers) and detect coherent interactions between the P1 centers and a local bath of

^{13} C

nuclear spins. The dipolar coupling between the P1 centers and

^{13} C

nuclear spins is identified by signature periodic collapses and revivals in the P1 spin coherence signal. We then demonstrate, using a range of dynamical decoupling protocols, that the probing NV centers and the P1 spins are coupled to independent ensembles of

^{13} C

nuclear spins. Our work illustrates how the optically dark P1 spins can be used to extract information from their local environment and offers new insight into the interactions within a many-body system.

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用顺磁氮自旋组合感知相干核自旋动态

中心自旋量子比特周围的非极化自旋环境通常被视为非相干的去相干源，然而，对自旋浴的精确表征和控制可以为量子态的存储和传感提供资源。在这项工作中，我们利用金刚石中的氮空位（NV）中心来测量光暗顺磁氮缺陷（P1 中心）的相干性，并探测 P1 中心与 13C 核自旋局部浴之间的相干相互作用。P1 中心和 13C 核自旋之间的双极耦合是通过 P1 自旋相干信号中的周期性坍缩和恢复特征来识别的。然后，我们利用一系列动态解耦协议证明，探测 NV 中心和 P1 自旋与独立的 13C 核自旋集合耦合。我们的工作说明了如何利用光暗 P1 自旋从其局部环境中提取信息，并为多体系统内的相互作用提供了新的见解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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