The decay of the refocused Hahn echo in double electron-electron resonance (DEER) experiments.

Q3 Physics and Astronomy

Magnetic resonance (Gottingen, Germany) Pub Date : 2021-04-16 eCollection Date: 2021-01-01 DOI:10.5194/mr-2-161-2021

Thorsten Bahrenberg, Samuel M Jahn, Akiva Feintuch, Stefan Stoll, Daniella Goldfarb

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Abstract

Double electron-electron resonance (DEER) is a pulse electron paramagnetic resonance (EPR) technique that measures distances between paramagnetic centres. It utilizes a four-pulse sequence based on the refocused Hahn spin echo. The echo decays with increasing pulse sequence length $2 (τ_{1} + τ_{2})$ , where $τ_{1}$ and $τ_{2}$ are the two time delays. In DEER, the value of $τ_{2}$ is determined by the longest inter-spin distance that needs to be resolved, and $τ_{1}$ is adjusted to maximize the echo amplitude and, thus, sensitivity. We show experimentally that, for typical spin centres (nitroxyl, trityl, and Gd(III)) diluted in frozen protonated solvents, the largest refocused echo amplitude for a given $τ_{2}$ is obtained neither at very short $τ_{1}$ (which minimizes the pulse sequence length) nor at $τ_{1} = τ_{2}$ (which maximizes dynamic decoupling for a given total sequence length) but rather at $τ_{1}$ values smaller than $τ_{2}$ . Large-scale spin dynamics simulations based on the coupled cluster expansion (CCE), including the electron spin and several hundred neighbouring protons, reproduce the experimentally observed behaviour almost quantitatively. They show that electron spin dephasing is driven by solvent protons via the flip-flop coupling among themselves and their hyperfine couplings to the electron spin.

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双电子电子共振（DEER）实验中重新聚焦的哈恩回波的衰减。

双电子电子共振（DEER）是一种测量顺磁中心之间距离的脉冲电子顺磁共振（EPR）技术。它利用基于重新聚焦的哈恩自旋回波的四脉冲序列。回波随着脉冲序列长度2（τ1+τ2）的增加而衰减，其中τ1和τ2是两个时间延迟。在DEER中，τ2的值由需要解析的最长自旋间距离决定，并调整τ1以使回波振幅最大化，从而使灵敏度最大化。我们通过实验表明，对于在冷冻质子化溶剂中稀释的典型自旋中心（硝基二甲苯、三苯甲基和Gd（III）），给定τ2的最大重聚焦回波振幅既不是在极短的τ1（使脉冲序列长度最小化），也不是在τ1=τ2（使给定总序列长度的动态解耦最大），而是在小于τ2的τ1值下获得。基于耦合团簇膨胀（CCE）的大规模自旋动力学模拟，包括电子自旋和数百个相邻质子，几乎定量地再现了实验观察到的行为。他们表明，电子自旋去相位是由溶剂质子通过它们之间的触发器耦合以及它们与电子自旋的超精细耦合来驱动的。

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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