高波数拉曼分析

Recent Developments in Atomic Force Microscopy and Raman Spectroscopy for Materials Characterization [Working Title] Pub Date : 2021-10-28 DOI:10.5772/intechopen.100474

Shan Yang

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引用次数: 2

摘要

拉曼光谱具有分子特异性，其在指纹区(200-2000 cm−1)的峰通常足以用于物质识别。高波数信号(> 2000 cm−1)在无机材料中很少见，但在含有轻氢原子的有机材料中却很丰富。关于高波数(HW)拉曼信号的报道远远少于指纹信号。这可能部分归因于难以获得HW拉曼信号，特别是从含有荧光蛋白的生物材料中。InGaAs阵列和近红外(NIR)激光器的发展和可用性使得从生物材料中获取不同的HW拉曼成为可能。在这一章中，我们将介绍近年来HW拉曼光谱在不同材料上的应用，特别是在生物组织上的应用。基于多激光器或多光谱仪的拉曼仪器也将被讨论。

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High-Wavenumber Raman Analysis

Raman spectra are molecule specific, and their peaks in the fingerprint region (200-2000 cm−1) are often sufficient for material identification. High-wavenumber signals (> 2000 cm−1) are rare in inorganic material but rich in organic materials containing light hydrogen atoms. Reports on high-wavenumber (HW) Raman signals are far less than fingerprint signals. This could be partially attributed to the difficulty obtaining HW Raman signals, especially from biological materials containing fluorescent proteins. The development and the availability of InGaAs array and the near-infrared (NIR) laser enabled the acquisition of distinct HW Raman from bio-materials. In this chapter, we will introduce recent applications of HW Raman spectroscopy on different materials, especially on biological tissues. Raman instrumentation based on multiple lasers or multiple spectrometers will also be discussed.

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Recent Developments in Atomic Force Microscopy and Raman Spectroscopy for Materials Characterization [Working Title]

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