13C-Formate as an indirect low-temperature 1H lineshape polarimeter

IF 2.624 Journal of Magnetic Resonance Open Pub Date : 2024-09-23 DOI:10.1016/j.jmro.2024.100162

Stuart J. Elliott , Quentin Stern, Sami Jannin

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Abstract

¹H polarization quantification is important for dissolution-dynamic nuclear polarization (dDNP) but can be cumbersome due to the requirement of acquiring thermal equilibrium signals and measurements that are complicated by large background signals. ¹H nuclear magnetic resonance (NMR) spectra can also be deleteriously influenced by line distortions linked with radiation damping from ¹H DNP and cannot be used for accurate calculation of ¹H polarization. Determining ¹H polarization via immediate ¹³C lineshape analysis of a simple molecule removes such complications. We present ¹³C-sodium formate as a straightforward system for indirect ¹H polarimetry. The ¹³C NMR spectra acquired under dDNP conditions have distinct features that are readily reproduced with ¹³C lineshape simulations. ¹H polarizations built-up during ¹H DNP were indirectly inferred by fitting simulations to ¹³C lineshapes. We provide the MATLAB scripts used for ¹³C lineshape analysis in order that the method can be readily implemented in other laboratories.

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作为间接低温 1H 线形偏振计的 13C 甲酸酯

1H 极化定量对于溶解-动态核极化（dDNP）非常重要，但由于需要获取热平衡信号，且测量工作因大量背景信号而变得复杂，因此可能非常麻烦。1H 核磁共振 (NMR) 图谱也会受到与 1H DNP 辐射阻尼有关的线畸变的有害影响，无法用于精确计算 1H 极化。通过对简单分子进行直接 13C 线形分析来确定 1H 极化，可以消除这些复杂问题。我们将 13C 甲酸钠作为间接 1H 极化测量的一个直接系统。在 dDNP 条件下获得的 13C NMR 光谱具有明显的特征，这些特征很容易通过 13C 线形模拟再现。通过模拟拟合 13C 线型，可间接推断出 1H DNP 期间建立的 1H 极化。我们提供了用于 13C 线形分析的 MATLAB 脚本，以便其他实验室也能方便地使用这种方法。

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 Open

CiteScore

1.90

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0.00%

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