摘要:缝隙增强拉曼探针(GERS)灵敏度高,信号稳定且具有多指标能力,在生物医学领域有着广阔的应用前景。本文合成了内嵌1,4-苯二硫醇(BDT)的金核壳纳米结构,并进行了紫外可见吸收、拉曼、透射电镜的表征;接着对内嵌不同分子的GERS探针进行了光稳定性测试;然后对颗粒进行了介孔硅的包覆。实验成功获得了不同BDT吸附时间的金核壳纳米胶体溶液,拉曼测试表明,随吸附时间的增加颗粒信号先增后减,在44h处最强;光稳定性测试表明,裸露的GERS探针稳定性不够好,但是通过包覆介孔硅能够有效地提高探针的光稳定性。
关键词 缝隙增强拉曼探针1,4-苯二硫醇光稳定性介孔硅包覆
毕业设计说明书外文摘要
Title Fabrication of Gap-Enhanced Raman Scattering Probes and Their Photostability Tests
Abstract:Gap-enhanced Raman scattering (GERS) probes are equipped with high sensitivity, stable signals and multiplexing capability, thus having good prospects for application. This paper first introduces the fabrication of 1,4-benzenedithiol (BDT) embedded gold core-shell nanostructure, followed by its characterizations by UV-vis spectra, Raman spectra and transmission microscopy. Next, photostability tests are done to GERS probes embedded with different Raman reporters. And then mesoporous silica coating is conducted. Colloidal solutions with nanoparticles of different BDT adsorption time were successfully achieved. The Raman spectra indicated that signals of the prepared nanoparticles first got stronger and then weaker when the adsorption time increased, and the strongest point was 44h. Photostability tests demonstrated that stability of bare GERS probes were not so good , but it could be improved after mesoporous silica coating.
Keywords Gap-enhanced Raman scattering probes 1,4-benzenedithiol Photostability Mesoporous silica coating
1引言1
1.1拉曼散射 1
1.2表面增强拉曼散射 2
1.3表面增强拉曼探针 3
1.4缝隙增强拉曼探针 7
1.5拉曼探针的光稳定性 7
1.6文章主要的工作和内容 8
2内嵌1,4-苯二硫醇的金纳米核壳结构的合成、表征及光稳定性测试9
2.1实验原料及仪器9
2.2实验方法10
2.3结果与讨论11
3内嵌联二巯基苯、三苯二巯基的金纳米核壳结构的光稳定性测试18
3.1实验原料、仪器和方法18
3.2结果与讨论18
3.3本章总结21
4内嵌1,4-苯二硫醇的金纳米核壳结构(30h)的介孔硅包覆及光稳定性测试22
4.1实验原料及仪器22
4.2实验方法22
4.3结果与讨论23结论28致谢29参考文献30
1 引言
1.1 拉曼散射
1.1.1 背景介绍
拉曼散射(Ramanscattering)指的是光的非弹性散射现象。奥地利物理学家AdolfSmekal在1923年最早预言了这种现象的存在。1928年,印度物理学家C.V.Raman和他的学生K.S.Krishnan在液体中发现了拉曼效应,随后,前苏联物理学家GrigoryLandsberg和LeonidMandelstam在晶体中观察到了这一现象。拉曼散射反映的是分子振动和转动方面的信息,所以从此拉曼散射光谱作为一种分析手段开始应用于分子分析领域[1]。
1.1.2 拉曼散射原理
当一束入射光透过不均匀的吸收介质时,入射光的方向会发生无规则的改变,这一现象便是光的散射[1]。当入射光遭到原子或分子的散射时,大部分的光子发生的是弹性散射,即只改变方向,不改变频率,称为瑞利(Rayleigh)散射;一小部分的光子(约千万分之一)在散射后不仅改变了方向,也改变了频率,这种现象称为拉曼散射。 缝隙增强拉曼探针的制备及其光稳定性测试:http://www.youerw.com/cailiao/lunwen_205152.html