Demystifying the Diffuse Vibrational Spectrum of Aqueous Protons Through Cold Cluster Spectroscopy.

IF 11.7 1区化学 Q1 CHEMISTRY, PHYSICAL Annual review of physical chemistry Pub Date : 2021-04-20 Epub Date: 2021-03-01 DOI:10.1146/annurev-physchem-061020-053456

Helen J Zeng, Mark A Johnson

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引用次数: 13

Abstract

The ease with which the pH is routinely determined for aqueous solutions masks the fact that the cationic product of Arrhenius acid dissolution, the hydrated proton, or H⁺(aq), is a remarkably complex species. Here, we review how results obtained over the past 30 years in the study of H⁺⋅(H₂O)_n cluster ions isolated in the gas phase shed light on the chemical nature of H⁺(aq). This effort has also revealed molecular-level aspects of the Grotthuss relay mechanism for positive-charge translocation in water. Recently developed methods involving cryogenic cooling in radiofrequency ion traps and the application of two-color, infrared-infrared (IR-IR) double-resonance spectroscopy have established a clear picture of how local hydrogen-bond topology drives the diverse spectral signatures of the excess proton. This information now enables a new generation of cluster studies designed to unravel the microscopic mechanics underlying the ultrafast relaxation dynamics displayed by H⁺(aq).

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用冷簇光谱学揭开水质子扩散振动谱的神秘面纱。

通常测定水溶液的pH值很容易，这掩盖了一个事实，即阿伦尼乌斯酸溶解的阳离子产物，水合质子，或H+(aq)，是一个非常复杂的物质。在这里，我们回顾了过去30年来在气相分离H+⋅(H2O)n簇离子的研究中获得的结果如何揭示了H+(aq)的化学性质。这项工作还揭示了Grotthuss接力机制在水中正电荷转运的分子水平方面。最近发展的方法包括射频离子阱中的低温冷却和双色红外-红外(IR-IR)双共振光谱的应用，已经建立了局部氢键拓扑如何驱动多余质子的各种光谱特征的清晰图像。这些信息使得新一代的簇研究能够揭示H+(aq)显示的超快弛豫动力学背后的微观力学。

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来源期刊

Annual review of physical chemistry 化学-物理化学

CiteScore

28.00

自引率

0.00%

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期刊介绍： The Annual Review of Physical Chemistry has been published since 1950 and is a comprehensive resource for significant advancements in the field. It encompasses various sub-disciplines such as biophysical chemistry, chemical kinetics, colloids, electrochemistry, geochemistry and cosmochemistry, chemistry of the atmosphere and climate, laser chemistry and ultrafast processes, the liquid state, magnetic resonance, physical organic chemistry, polymers and macromolecules, and others.

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