Time- and Space-Resolved Vibrational Spectroscopic Approaches to Elucidate the Behaviors of Complex Molecular Systems: From Biological Cells to Hybrid Solar-Cell Materials: ―細胞からハイブリッド太陽電池材料まで―

Shinsuke Shigeto
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Abstract

Elucidation of the behaviors of complex molecular systems is central to controlling their elaborate functions. It requires approaches that bear time and space specificities as well as chemical specificity, because various kinds of molecules act at different times and locations in order to carry out particular molecular processes. Timeand spaceresolved vibrational spectroscopies are a powerful method that can meet all of these requirements. This Account shows how these approaches enable us to investigate complex molecular systems including living cells, bacterial communities known as biofilms, and solar-cell materials. Raman microspectroscopy in combination with multivariate data analysis reveals dynamic changes in the concentrations and distributions of cellular components such as proteins and lipids, during the cell cycle without the need for labeling. It is also applied to study bacterial biofilms in a nondestructive manner with a focus on their metabolites (carotenoids in the present case). Nanosecond time-resolved IR spectroscopy is used to observe distinct transient species generated after photoexcitation in organic– inorganic hybrid perovskite solar cells, which are attracting tremendous interest of researchers as a promising next-generation photovoltaic device. The results presented here highlight that deciphering timeand space-resolved vibrational spectra has unraveled a number of new phenomena that are of relevance to biological/material functions.
时间和空间分辨振动光谱方法阐明复杂分子系统的行为:从生物细胞到混合太阳能电池材料
阐明复杂分子系统的行为是控制其复杂功能的核心。它需要具有时间和空间特异性以及化学特异性的方法,因为各种分子在不同的时间和地点起作用,以进行特定的分子过程。时间和空间分辨振动光谱是一种强大的方法,可以满足所有这些要求。本书展示了这些方法如何使我们能够研究复杂的分子系统,包括活细胞、被称为生物膜的细菌群落和太阳能电池材料。拉曼显微光谱与多变量数据分析相结合,揭示了细胞周期中细胞成分(如蛋白质和脂质)浓度和分布的动态变化,而无需标记。它还应用于以非破坏性方式研究细菌生物膜,重点是它们的代谢物(在本例中为类胡萝卜素)。利用纳秒时间分辨红外光谱观测有机-无机杂化钙钛矿太阳能电池光激发后产生的不同瞬态物质,是一种极具发展前景的下一代光伏器件。本文提出的结果强调,破译时间和空间分辨振动谱揭示了一些与生物/材料功能相关的新现象。
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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