Non-commutative perturbation theory for spin dynamics explains the factorization properties of RIDME background

IF 2 3区化学 Q3 BIOCHEMICAL RESEARCH METHODS

Journal of magnetic resonance Pub Date : 2024-07-02 DOI:10.1016/j.jmr.2024.107729

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Abstract

The intermolecular hyperfine relaxation-induced dipolar modulation enhancement (ih-RIDME) experiment has a promising potential to quantitatively characterize the nuclear environment in the 0.8-3 nm range around an electron spin. Such information about the spatial arrangement of nuclei is of great interest for structural biology as well as for dynamic nuclear polarization (DNP) methods. In order to develop a reliable and sensitive spectroscopic tool, a solid data model needs to be established. Here, we attempt to provide a theoretical explanation for the experimentally observed properties of the ih-RIDME signal. Our main approach uses a perturbation expansion of the Baker–Campbell–Hausdorff formula during the transverse evolution of the electron spin, treating the nuclear dipolar Hamiltonian as a perturbation. We show that a product structure of the ih-RIDME signal follows directly from the statistical independence of the perturbation terms and the multinuclear hyperfine coupling, and that this signal composition is expected when the mixing time exceeds the 95% decay of the Hahn echo.

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自旋动力学的非交换性扰动理论解释了 RIDME 背景的因式分解特性

分子间超频弛豫诱导的偶极调制增强（ih-RIDME）实验在定量描述电子自旋周围 0.8-3 纳米范围内的核环境特征方面具有广阔的前景。这种有关原子核空间排列的信息对于结构生物学和动态核极化（DNP）方法都具有重大意义。为了开发可靠灵敏的光谱工具，需要建立一个可靠的数据模型。在此，我们试图为实验观察到的 ih-RIDME 信号特性提供理论解释。我们的主要方法是在电子自旋横向演化过程中使用贝克-坎贝尔-豪斯多夫公式的扰动扩展，将核双极性哈密顿视为一种扰动。我们的研究表明，ih-RIDME 信号的乘积结构直接源于扰动项和多核超细耦合的统计独立性，而且当混合时间超过哈恩回波 95% 衰减时，这种信号组成是可以预期的。

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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来源期刊

Journal of magnetic resonance 物理-光谱学

CiteScore

3.80

自引率

13.60%

发文量

150

审稿时长

69 days

期刊介绍： The Journal of Magnetic Resonance presents original technical and scientific papers in all aspects of magnetic resonance, including nuclear magnetic resonance spectroscopy (NMR) of solids and liquids, electron spin/paramagnetic resonance (EPR), in vivo magnetic resonance imaging (MRI) and spectroscopy (MRS), nuclear quadrupole resonance (NQR) and magnetic resonance phenomena at nearly zero fields or in combination with optics. The Journal''s main aims include deepening the physical principles underlying all these spectroscopies, publishing significant theoretical and experimental results leading to spectral and spatial progress in these areas, and opening new MR-based applications in chemistry, biology and medicine. The Journal also seeks descriptions of novel apparatuses, new experimental protocols, and new procedures of data analysis and interpretation - including computational and quantum-mechanical methods - capable of advancing MR spectroscopy and imaging.