顺磁核磁共振:工具包

IF 3.1 4区 化学 Q2 CHEMISTRY, INORGANIC & NUCLEAR
Leonardo Querci, Letizia Fiorucci, E. Ravera, Mario Piccioli
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引用次数: 0

摘要

核磁共振(NMR)光谱是研究无机物和生物物质的结构、反应性和动力学的理想工具。有关核自旋相互作用和自旋动力学的知识日益巩固,从而可以定制脉冲序列。在处理顺磁系统时,经过数十年的研究,已经开发出了优化实验的经验法则标准,从而可以探测非常接近金属中心的原子核。反过来,对这些系统的观测,再加上稳健易行的量子化学方法的发展,有望通过对电子结构的解释,在光谱和结构特征之间建立联系。在这篇综述中,我们列出了所遇到的挑战,并提出了处理顺磁系统最满意的解决方案。按照我们的意图,这是一套实用的工具包,用于优化常规实验的采集和处理参数,目的是检测受超细相互作用影响的信号。我们还研究了顺磁偏移和线宽的影响。通过这一努力,我们希望鼓励非专业用户考虑在其系统中应用顺磁核磁共振。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Paramagnetic Nuclear Magnetic Resonance: The Toolkit
Nuclear Magnetic Resonance (NMR) spectroscopy is the ideal tool to address the structure, reactivity and dynamics of both inorganic and biological substances. The knowledge of nuclear spin interaction and spin dynamics is increasingly consolidated, and this allows for tailoring pulse sequences. When dealing with paramagnetic systems, several decades of research have led to the development of rule-of-the-thumb criteria for optimizing the experiments, allowing for the detection of nuclei that are in very close proximity to the metal center. In turn, the observation of these systems, coupled with the development of robust and accessible quantum chemical methods, is promising to provide a link between the spectra and the structural features through the interpretation of the electronic structure. In this review, we list the challenges encountered and propose solutions for dealing with paramagnetic systems with the greatest satisfaction. In our intentions, this is a practical toolkit for optimizing acquisition and processing parameters for routine experiments aimed at detecting signals influenced by the hyperfine interaction. The implications of paramagnetic shift and line broadening are examined. With this endeavor, we wish to encourage non-expert users to consider the application of paramagnetic NMR to their systems.
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来源期刊
Inorganics
Inorganics Chemistry-Inorganic Chemistry
CiteScore
2.80
自引率
10.30%
发文量
193
审稿时长
6 weeks
期刊介绍: Inorganics is an open access journal that covers all aspects of inorganic chemistry research. Topics include but are not limited to: synthesis and characterization of inorganic compounds, complexes and materials structure and bonding in inorganic molecular and solid state compounds spectroscopic, magnetic, physical and chemical properties of inorganic compounds chemical reactivity, physical properties and applications of inorganic compounds and materials mechanisms of inorganic reactions organometallic compounds inorganic cluster chemistry heterogenous and homogeneous catalytic reactions promoted by inorganic compounds thermodynamics and kinetics of significant new and known inorganic compounds supramolecular systems and coordination polymers bio-inorganic chemistry and applications of inorganic compounds in biological systems and medicine environmental and sustainable energy applications of inorganic compounds and materials MD
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