Complete multinuclear solid-state NMR of metal-organic frameworks: The case of α-Mg-formate

IF 0.4 4区化学 Q4 CHEMISTRY, PHYSICAL

Concepts in Magnetic Resonance Part A Pub Date : 2017-12-05 DOI:10.1002/cmr.a.21410

Bryan E. G. Lucier, Yue Zhang, Yining Huang

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引用次数: 10

Abstract

Metal-organic frameworks (MOFs) are exciting porous materials with a growing number of applications ranging from catalysis to gas storage. Establishing logical connections between the local MOF structure and its properties is not often straightforward, however, solid-state NMR is a sensitive probe of local structure and can be used to shed light on processes such as guest adsorption and gas motion within MOFs. As illustrated using our recent works on the microporous α-Mg-formate (Mg₃(HCOO)₆) MOF, complete multinuclear solid-state NMR characterization of MOFs is now possible, and can provide unique insight that is not readily available through other methods. A wide variety of solid-state NMR techniques have been employed, including direct-excitation, cross-polarization, fast magic-angle spinning, and two-dimensional experiments. New variable-temperature ²H solid-state NMR data of deuterated hydrogen gas within α-Mg-formate and the resulting detailed dynamic information is also presented, analyzed, and discussed.

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金属-有机骨架的完整多核固体核磁共振:α- mg -甲酸酯的情况

金属有机框架(mof)是一种令人兴奋的多孔材料，从催化到气体储存的应用越来越多。建立局部MOF结构与其性质之间的逻辑联系通常并不简单，然而，固态核磁共振是局部结构的敏感探针，可用于阐明MOF内部的客体吸附和气体运动等过程。正如我们最近对微孔α- mg -甲酸酯(Mg3(HCOO)6) MOF的研究所表明的那样，MOF的完整多核固态核磁共振表征现在是可能的，并且可以提供通过其他方法不易获得的独特见解。各种固态核磁共振技术已被广泛采用，包括直接激发、交叉极化、快速魔角旋转和二维实验。本文还介绍了α- mg -甲酸酯中氘化氢气的2H固态变温核磁共振数据及其详细的动态信息。

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

Concepts in Magnetic Resonance Part A 物理-光谱学

CiteScore

0.90

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Concepts in Magnetic Resonance Part A brings together clinicians, chemists, and physicists involved in the application of magnetic resonance techniques. The journal welcomes contributions predominantly from the fields of magnetic resonance imaging (MRI), nuclear magnetic resonance (NMR), and electron paramagnetic resonance (EPR), but also encourages submissions relating to less common magnetic resonance imaging and analytical methods. Contributors come from academic, governmental, and clinical communities, to disseminate the latest important experimental results from medical, non-medical, and analytical magnetic resonance methods, as well as related computational and theoretical advances. Subject areas include (but are by no means limited to): -Fundamental advances in the understanding of magnetic resonance -Experimental results from magnetic resonance imaging (including MRI and its specialized applications) -Experimental results from magnetic resonance spectroscopy (including NMR, EPR, and their specialized applications) -Computational and theoretical support and prediction for experimental results -Focused reviews providing commentary and discussion on recent results and developments in topical areas of investigation -Reviews of magnetic resonance approaches with a tutorial or educational approach