Isolating solvent–solute hydrogen bonding interactions via 2D IR solvation shell spectroscopy

溶剂化 溶剂化壳 分子间力 氢键 化学物理 化学 光谱学 红外光谱学 分子 分子动力学 非谐性 旋转-振动耦合 溶剂 计算化学 溶剂效应 物理化学 分子振动 塔特布 吸收光谱法 壳体(结构) 材料科学 联轴节(管道)
作者
Samuel Knight,Nicholas H. C. Lewis,Ian J. A. Bongalonta,John H. Hack,Yumin Lee,Andrei Tokmakoff
出处
期刊:Journal of Chemical Physics [American Institute of Physics]
卷期号:164 (12)
标识
DOI:10.1063/5.0316253
摘要

The solvation shell around a solute is a fundamental feature of liquid-phase solutions, determining the behavior and properties of both the solute and the overall solution. Direct experimental measurements of the solvation shell properties are challenging due to the strong signals generated from the bulk solvent, which overwhelm the small contribution of the solvation shell. Here, we use ultrafast two dimensional infrared (2D IR) spectroscopy and intermolecular cross-peaks to isolate the IR absorption spectrum of methanol molecules in the solvation shell surrounding the solute N-methylacetamide. We demonstrate that the intermolecular coupling between the solvent and solute vibrations is indirectly mediated by a low-frequency hydrogen-bonding mode, suggesting an important mechanism for anharmonic coupling induced by hydrogen bonds. From the relative frequency shifts and cross-peak anisotropy, we find that methanol molecules surrounding N-methylacetamide form stronger and distinctly oriented hydrogen bonds than those in the bulk solvent. We also compare these results with the solvent spectra of the solute N,N-dimethylacetamide to investigate how solute structural changes alter the solvation shell and the contribution of N-H hydrogen bond donation. Our results are supported by molecular dynamics simulations, which provide detailed insights into the hydrogen-bonding distributions. Through these results, we demonstrate 2D solvation shell spectroscopy to be a valuable method for investigating solvation structures and dynamics without interference from the bulk solvent.
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