Imaging of Three-dimensional Orientation of Molecules in Polymers Using FT-IR, Raman, and O-PTIR Microspectroscopies

Proceedings of the 8th World Congress on Mechanical, Chemical, and Material Engineering Pub Date : 2022-08-01 DOI:10.11159/iccpe22.118

Karolina Kosowska, P. Koziol, D. Liberda, T. Wróbel

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Abstract

Extended Abstract Fourier transform infrared microspectroscopy (FT-IR) is a nondestructive, information-rich, and label-free technique successfully applied for years in material science. The introduction of linear polarization enriches the technique with the possibility of studying the orientation of macromolecules. Until now, experiments focused on using the absorbance of a single band to retrieve the in-plane orientation and the degree of order. The extended four-polarization (4P) method, which enables the visualization of the macromolecule orientation regardless of the choice of the direction of polarization, was proposed by Hikima et al. for polymers [1]. The application of IR imaging with 4P on heterogeneous structure, human tissue microarrays, was presented for the first time by our team in 2020 [2], [3]. A deeper characterization of the sample structure is the next step. Simultaneous analysis of two bands of roughly perpendicular transition moment orientations was proposed by Lee in 2018 as a method of determining the orientation of the molecule in three-dimensional space [4]. The first application of “concurrent analysis” (4P-3D) to

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利用FT-IR，拉曼和O-PTIR显微光谱成像聚合物分子的三维取向

傅里叶变换红外微光谱学(FT-IR)是一种无损的、信息丰富的、无标记的技术，多年来在材料科学中得到了成功的应用。线偏振的引入使研究大分子取向的技术变得更加丰富。到目前为止，实验主要是利用单波段的吸光度来检索面内取向和有序度。Hikima等人针对聚合物[1]提出了扩展的四极化(4P)方法，无论选择极化方向如何，都可以实现大分子取向的可视化。我们的团队在2020年首次提出了4P红外成像在异质结构人体组织微阵列上的应用。下一步是对样品结构进行更深入的表征。Lee在2018年提出了同时分析两个大致垂直的过渡矩方向带，作为确定分子在三维空间[4]中的方向的方法。“并发分析”(4d - 3d)的首次应用

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Proceedings of the 8th World Congress on Mechanical, Chemical, and Material Engineering

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