作者:孙萌涛、全军
页数:164
出版社:清华大学出版社
出版日期:2019
ISBN:9787302519201
电子书格式:pdf/epub/txt
内容简介
《等离激元增强荧光:原理和应用》适用于物理、光学、化学和材料学等专业科研院所和高校的研究人员、研究生及高年级本科生使用。
作者简介
孙萌涛教授,主要从事基于表面等离激元增强的分子拉曼光谱的实验和理论研究。研发高真空针尖增强拉曼和荧光光谱仪,实现目标分子拉曼光谱的超灵敏检测,并揭示表面等离激元增强拉曼光谱的物理和化学机制。以通讯作者(或第一作者)在国际重要学术期刊上发表SCI 论文超过150 篇(其中ESI 高引论文8篇)。所有论文引用约4800多次,H-index 36。Researcher ID: B-1131-2008。10次应邀在国际重要期刊撰写本领域的综述。应邀撰写英文专著(科学出版社)2 本(第一作者)。2016 年,获辽宁省科学技术(自然科学)二等奖(个人第二)。专著:
1. Mengtao Sun, et al., Photoinduced Electron Transfer in organic Solar Cell: Principle and Applications, 科学出版社, 2017年.
2. Mengtao Sun, et al., Tip-enhanced Raman and fluorescence spectroscopy, 科学出版社, 2017年.
本书特色
本书将从原理和应用两个方面详细介绍多种环境下的等离激元增强荧光。基于局域表面等离激元共振的等离激元能提供荧光所需要电子和能量,在表面等离激元增强荧光,针尖增强荧光光谱,表面等离激元增强上转换荧光材料,表面等离激元增强的共振荧光能转移的过程中发现等离激元能选择性增强分子或材料体系的荧光。
目录
Plasmon睧nhanced Fluorescence: Principles and Applications
CONTENTS
Chapter ⅠIntroduction
References
Chapter ⅡPhysical Mechanism of Plasmon睧nhanced Fluorescence
2.1Introduction
2.2The principle of PEF
References
Chapter ⅢPlasmon睧nhanced Fluorescence
3.1Introduction
3.2PEF from periodical metallic plasmonic nanostructures
3.2.1PEF from nanograting substrate
3.2.2PEF from nanohole arrays substrate
3.2.3PEF from nanoparticle arrays substrate
3.2.4PEF from nanorod arrays substrate
3.3PEF from nonperiodical metallic plasmonic nanostructure
3.3.1PEF from metallic silver island substrate
3.3.2PEF from metallic fractal瞝ike substrate
3.3.3PEF from deposited metallic nanoparticle substrate
3.4The wavelength and spacer effect towards the fluorescence
enhancement
3.5Conclusion and prospect
References
Chapter ⅣTip睧nhanced Fluorescence
4.1Introduction
4.2Experimental works on tip瞖nhanced fluorescence
4.3Theoretical calculations on tip瞖nhanced Raman
spectroscopy
4.4Results and discussion
4.5Conclusion and outlook
References
Chapter ⅤPlasmon睧nhanced Upconversion Photoluminescence:
Physical Mechanism and Applications
5.1Introduction
5.2Mechanism model of upconversion fluorescence
5.3Plasmon瞖nhanced upconversion
5.3.1Plasmon瞖nhanced upconversion photoluminescence
from periodic plasmonic nanostructures
5.3.2Plasmon瞖nhanced upconversion photoluminescence
from nonperiodic plasmonic nanostructures
5.4Plasmon瞖nhanced from single rare瞖arth瞕oped
nanoparticles
5.5The applications of plasmon瞖nhanced UC luminescence
5.6Conclusion
References
Chapter ⅥTime睷esolved Plasmon睧nhanced Fluorescence for
Exciton睵lasmon Interaction
6.1Introduction
6.2Two methods for the exciton瞤lasmon coupling
6.2.1The first method
6.2.2The second method
6.3Conclusion
References
Chapter ⅦPlasmon睧nhanced Fluorescence Resonance Energy Transfer
7.1Introduction
7.2Fluorescence resonance energy transfer
7.2.1The definition and physical mechanism of FRET
7.2.2Methods to measure FRET efficiency
7.2.3Applications of FRET
7.3Plasmon瞖nhanced fluorescence
7.3.1The principle of PEF
7.3.2Principle of PE睩RET
7.3.3Application of PE睩RET
7.4Summary
References
ACKNOWLEDGEMENTS
