The solid effect of dynamic nuclear polarization in liquids – accounting for g-tensor anisotropy at high magnetic fields

Q3 Physics and Astronomy

Magnetic resonance (Gottingen, Germany) Pub Date : 2023-11-01 DOI:10.5194/mr-4-243-2023

Deniz Sezer, Danhua Dai, Thomas F. Prisner

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Abstract

Abstract. In spite of its name, the solid effect of dynamic nuclear polarization (DNP) is also operative in viscous liquids, where the dipolar interaction between the polarized nuclear spins and the polarizing electrons is not completely averaged out by molecular diffusion on the timescale of the electronic spin–spin relaxation time. Under such slow-motional conditions, it is likely that the tumbling of the polarizing agent is similarly too slow to efficiently average the anisotropies of its magnetic tensors on the timescale of the electronic T2. Here we extend our previous analysis of the solid effect in liquids to account for the effect of g-tensor anisotropy at high magnetic fields. Building directly on the mathematical treatment of slow tumbling in electron spin resonance (Freed et al., 1971), we calculate solid-effect DNP enhancements in the presence of both translational diffusion of the liquid molecules and rotational diffusion of the polarizing agent. To illustrate the formalism, we analyze high-field (9.4 T) DNP enhancement profiles from nitroxide-labeled lipids in fluid lipid bilayers. By properly accounting for power broadening and motional broadening, we successfully decompose the measured DNP enhancements into their separate contributions from the solid and Overhauser effects.

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液体中动态核极化的固体效应——考虑高磁场下g张量各向异性

摘要尽管它的名字，动态核极化(DNP)的固体效应也在粘性液体中起作用，其中极化核自旋和极化电子之间的偶极相互作用在电子自旋-自旋弛豫时间尺度上并没有完全被分子扩散平均。在这种慢运动条件下，极化剂的翻滚很可能同样太慢，无法在电子T2的时间尺度上有效地平均其磁张量的各向异性。在这里，我们扩展了之前对液体中固体效应的分析，以解释高磁场下g张量各向异性的影响。直接建立在电子自旋共振中缓慢翻滚的数学处理(Freed et al.， 1971)的基础上，我们计算了在液体分子的平移扩散和极化剂的旋转扩散存在下的固体效应DNP增强。为了说明这种形式，我们分析了流体脂质双层中氮氧化物标记的脂质的高场(9.4 T) DNP增强剖面。通过适当地考虑功率展宽和情绪展宽，我们成功地将测量的DNP增强分解为固体效应和Overhauser效应的单独贡献。

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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