Raman scattering of water in vicinity of polar complexes: Computational insight into baseline subtraction.

Spectrochimica acta. Part A, Molecular and biomolecular spectroscopy Pub Date : 2025-03-15 Epub Date: 2024-12-20 DOI:10.1016/j.saa.2024.125648

Christina Karafyllia, Jiří Kessler, Jana Hudecová, Josef Kapitán, Petr Bouř

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Abstract

Water is a greatly convenient solvent in Raman spectroscopy. However, non-additive effects sometimes make its signal difficult to subtract. To understand these effects, spectra for clusters of model ions, including transition metal complexes and water molecules, were simulated and analyzed. A combined molecular mechanics/quantum mechanics approach was taken to reveal how relative Raman scattering intensities depend on the distance from the solute and the excitation wavelength. The computations indicate a big effect of solute charge; for example, the sodium cation affects Raman scattering by water to a lesser extent than the chlorine anion. The modeling was able to qualitatively reproduce the experimental observation that a solution of a simple salt may work as a baseline better than pure water in many Raman experiments. For absorbing species, an additional scattering boost occurs due to the resonance effect. Simulations thus provide useful insight into solute-solvent interactions and their effects on measured spectra.

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极性络合物附近水的拉曼散射：基线减法的计算洞察力。

在拉曼光谱中，水是一种非常方便的溶剂。然而，非加性效应有时使其信号难以相减。为了理解这些影响，模拟和分析了模型离子簇（包括过渡金属配合物和水分子）的光谱。采用分子力学/量子力学相结合的方法揭示了相对拉曼散射强度如何依赖于与溶质的距离和激发波长。计算表明，溶质电荷的影响较大；例如，钠离子对水的拉曼散射的影响程度小于氯阴离子。该模型能够定性地再现实验观察，即在许多拉曼实验中，简单盐溶液可能比纯水溶液更好地作为基线。对于吸收物质，由于共振效应，会产生额外的散射增强。因此，模拟为溶质-溶剂相互作用及其对测量光谱的影响提供了有用的见解。

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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Spectrochimica acta. Part A, Molecular and biomolecular spectroscopy

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