Surface-Enhanced Raman Scattering: Introduction and Applications

Recent Advances in Nanophotonics - Fundamentals and Applications Pub Date : 2020-05-21 DOI:10.5772/intechopen.92614

Samir Kumar, Prabhat Kumar, Anamika Das, Chandra Shakher Pathak

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引用次数: 20

Abstract

Scattering of light by molecules can be elastic, Rayleigh scattering, or inelastic, Raman scattering. In the elastic scattering, the photon’s energy and the state of the molecule after the scattering events are unchanged. Hence, Rayleigh scattered light does not contain much information on the structure of molecular states. In inelastic scattering, the frequency of monochromatic light changes upon interaction with the vibrational states, or modes, of a molecule. With the advancement in the laser sources, better and compact spectrometers, detectors, and optics Raman spectroscopy have developed as a highly sensitive technique to probe structural details of a complex molecular structure. However, the low scattering cross section (10−31) of Raman scattering has limited the applications of the conventional Raman spectroscopy. With the discovery of surface-enhanced Raman scattering (SERS) in 1973 by Martin Fleischmann, the interest of the research community in Raman spectroscopy as an analytical method has been revived. This chapter aims to familiarize the readers with the basics of Raman scattering phenomenon and SERS. This chapter will also discuss the latest developments in the SERS and its applications in various fields.

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表面增强拉曼散射:介绍与应用

分子的光散射可以是弹性的瑞利散射，也可以是非弹性的拉曼散射。在弹性散射中，光子的能量和散射后分子的状态是不变的。因此，瑞利散射光不包含很多关于分子状态结构的信息。在非弹性散射中，单色光的频率随着与分子的振动状态或模式的相互作用而改变。随着激光光源的进步，性能更好、结构更紧凑的光谱仪、探测器和光学拉曼光谱技术已经发展成为一种高灵敏度的技术，可以探测复杂分子结构的结构细节。然而，拉曼散射的低散射截面(10−31)限制了传统拉曼光谱的应用。随着1973年马丁·弗莱希曼(Martin Fleischmann)发现表面增强拉曼散射(SERS)，研究界对拉曼光谱作为一种分析方法的兴趣已经恢复。本章旨在使读者熟悉拉曼散射现象和SERS的基础知识。本章还将讨论SERS的最新发展及其在各个领域的应用。

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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Recent Advances in Nanophotonics - Fundamentals and Applications

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