揭示吲哚在水溶液和乙醇溶液中的光离子化动力学

IF 2.8 2区 化学 Q3 CHEMISTRY, PHYSICAL
Gaurav Kumar, Michael Kellogg, Shivalee Dey, Thomas A. A. Oliver* and Stephen E. Bradforth*, 
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引用次数: 0

摘要

在 292、268 和 200 纳米波长的激发下,使用超快瞬态吸收光谱法研究了色氨酸的紫外 B 发色团吲哚在水和乙醇中的光离子化动力学。通过研究吲哚在两种不同溶剂中从飞秒到纳秒的动态变化,我们建立了一个新的光物理模型,该模型解释了吲哚复杂的溶液相光化学过程中许多以前尚未解决的问题。光离子化只是吲哚在水溶液中的一个活跃途径,它导致荧光量子产率在富水环境中降低,而这一量子产率在生物物理实验中经常被用作蛋白质折叠状态的关键标志。在所有三种泵浦波长下,都观察到了水溶液中吲哚的光离子化现象,但这是通过两种不同的机制实现的。在 200 nm 波长的激发下,电子以弹道方式直接射入大量溶剂中。相反,292 nm 和 268 nm 激发则会产生两个 1ππ* 态,它们与紧密结合的吲哚阳离子和电子-离子对形成动态平衡。离子对在纳秒级的时间内解离,产生分离的溶解电子和吲哚阳离子。这些带电物种是产生三重吲哚的重要前体,大大提高了整个系统间的交叉率。我们提出的水溶液中吲哚的光物理模型最适合描述多肽序列中色氨酸的光诱导动力学;与多肽不同,色氨酸在 pH 值为 7 的水溶液中是齐聚离子,因此具有竞争性激发态质子转移途径,可以淬灭色氨酸荧光。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Unraveling the Photoionization Dynamics of Indole in Aqueous and Ethanol Solutions

Unraveling the Photoionization Dynamics of Indole in Aqueous and Ethanol Solutions

Unraveling the Photoionization Dynamics of Indole in Aqueous and Ethanol Solutions

The photoionization dynamics of indole, the ultraviolet-B chromophore of tryptophan, were explored in water and ethanol using ultrafast transient absorption spectroscopy with 292, 268, and 200 nm excitation. By studying the femtosecond-to-nanosecond dynamics of indole in two different solvents, a new photophysical model has been generated that explains many previously unsolved facets of indole’s complex solution phase photochemistry. Photoionization is only an active pathway for indole in aqueous solution, leading to a reduction in the fluorescence quantum yield in water-rich environments, which is frequently used in biophysical experiments as a key signature of the protein-folded state. Photoionization of indole in aqueous solution was observed for all three pump wavelengths but via two different mechanisms. For 200 nm excitation, electrons are ballistically ejected directly into the bulk solvent. Conversely, 292 and 268 nm excitation populates an admixture of two 1ππ* states, which form a dynamic equilibrium with a tightly bound indole cation and electron–ion pair. The ion pair dissociates on a nanosecond time scale, generating separated solvated electrons and indole cations. The charged species serve as important precursors to triplet indole production and greatly enhance the overall intersystem crossing rate. Our proposed photophysical model for indole in aqueous solution is the most appropriate for describing photoinduced dynamics of tryptophan in polypeptide sequences; tryptophan in aqueous pH 7 solution is zwitterionic, unlike in peptides, and resultantly has a competitive excited state proton transfer pathway that quenches the tryptophan fluorescence.

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来源期刊
CiteScore
5.80
自引率
9.10%
发文量
965
审稿时长
1.6 months
期刊介绍: An essential criterion for acceptance of research articles in the journal is that they provide new physical insight. Please refer to the New Physical Insights virtual issue on what constitutes new physical insight. Manuscripts that are essentially reporting data or applications of data are, in general, not suitable for publication in JPC B.
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