液态核磁共振中的样品对流：为何它一直存在，以及我们对此能做些什么。

Sample convection in liquid-state NMR: why it is always with us, and what we can do about it.

作者信息

Swan I, Reid M, Howe P W A, Connell M A, Nilsson M, Moore M A, Morris G A

机构信息

School of Chemistry, University of Manchester, Oxford Road, Manchester M13 9PL, UK.

Syngenta, Jealott's Hill Research Centre, Bracknell RG42 6EY, UK.

出版信息

J Magn Reson. 2015 Mar;252:120-9. doi: 10.1016/j.jmr.2014.12.006. Epub 2014 Dec 27.

DOI:10.1016/j.jmr.2014.12.006

PMID:25681799

Abstract

Many NMR experiments on liquids suffer if the sample convects. This is particularly true for applications, such as the measurement of diffusion, that rely on spatial labelling of spins. It is widely assumed that, in most well-conducted experiments with stable temperature regulation, samples do not convect. Unfortunately this is not the case. It is shown here that typical NMR samples show measurable convective flow for all but a very narrow range of temperatures; convection is seen both above and below this range, which can be as small as a degree or so for a mobile solvent such as chloroform. This convection is driven by both vertical and horizontal temperature gradients. Measurements of convection velocity are presented for a range of samples, sample tubes, probes, and temperatures. Both decreasing sample tube inner diameter and changing sample tube material from glass to sapphire can slow convection markedly, with sapphire tubes being particularly effective. Such tubes are likely to be particularly helpful for accurate measurement of diffusion by NMR.

摘要

如果样品发生对流，许多针对液体的核磁共振（NMR）实验都会受到影响。对于诸如扩散测量等依赖于自旋空间标记的应用而言，情况尤其如此。人们普遍认为，在大多数温度调节稳定且操作得当的实验中，样品不会发生对流。但遗憾的是，实际并非如此。本文表明，典型的NMR样品在除了非常窄的温度范围之外，都会出现可测量的对流；在该温度范围之上和之下都会观察到对流，对于像氯仿这样的流动溶剂，该温度范围可能小至1摄氏度左右。这种对流是由垂直和水平温度梯度驱动的。给出了一系列样品、样品管、探头和温度下的对流速度测量结果。减小样品管内径以及将样品管材料从玻璃换成蓝宝石，都能显著减缓对流，蓝宝石管的效果尤为显著。这种管子可能对通过NMR准确测量扩散特别有帮助。

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液态核磁共振中的样品对流：为何它一直存在，以及我们对此能做些什么。

Sample convection in liquid-state NMR: why it is always with us, and what we can do about it.

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