Dynamic nuclear polarization mechanism in isolated NV-centers at high magnetic fields

IF 2.624 Journal of Magnetic Resonance Open Pub Date : 2024-11-23 DOI:10.1016/j.jmro.2024.100178

Shubham Kumar Debadatta, Sheetal Kumar Jain

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Abstract

Nitrogen vacancy centers in diamonds are promising spin-based quantum sensors and qubits. These optically addressable paramagnetic point defects have the potential to allow efficient dynamic nuclear polarization (DNP) under ambient conditions due to their large electron spin polarization and long spin coherence time. NV-based DNP studies have shown significant sensitivity enhancement of ¹³C nuclear magnetic resonance (NMR). In this work, we present an analytical theory using a density matrix and average Hamiltonian theory for NV-¹³C spin system under varying magnetic fields, internal interaction strengths, and microwave irradiation parameters. We use a reduced basis approach under selective excitation of a single quantum transition in NV-center electron spin levels to derive the expressions for the matching conditions, effective Hamiltonian and polarization transfer frequency. Our results provide insight into the optimal experimental conditions for efficient DNP and the impact of the internal interactions on the DNP performance. The theoretical predictions are verified using numerical simulations.

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高磁场下孤立 NV 中心的动态核极化机制

钻石中的氮空位中心是很有前途的自旋量子传感器和量子比特。由于电子自旋极化大、自旋相干时间长，这些可光学处理的顺磁点缺陷具有在环境条件下实现高效动态核极化（DNP）的潜力。基于 NV 的 DNP 研究表明，13C 核磁共振 (NMR) 的灵敏度显著提高。在这项工作中，我们利用密度矩阵和平均哈密顿理论提出了在不同磁场、内部相互作用强度和微波辐照参数条件下 NV-13C 自旋系统的分析理论。我们采用还原基方法，在 NV 中心电子自旋水平的单量子跃迁选择性激发下，推导出匹配条件、有效哈密顿和极化转移频率的表达式。我们的结果为高效 DNP 的最佳实验条件以及内部相互作用对 DNP 性能的影响提供了启示。理论预测通过数值模拟得到了验证。

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来源期刊

Journal of Magnetic Resonance Open

CiteScore

1.90

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0.00%

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