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Title:
Surface-Enhanced Raman Scattering - Physics and Applications (Topics in Applied Physics Volume 103) |
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Division: General Anal Chem / Springer / 英文版 |
Author/Editor: Katrin Kneipp, Martin Moskovits, and Harald Kneipp Star:  |
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ISBN: 3540335668 |
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Introduce Date: 2007年10月18日18:49 , Release Date: 2007年10月18日19:17 |
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Introducer: sally208 , Rate: 6/293 |
| Format: pdf(editorial) Download |
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| Description: |
The book is divided into two parts. The first section begins with the basic physics behind SERS, providing both an overview and a summary of recent developments in the field. The electromagnetic theory of SERS is introduced by Martin Moskovits. George Schatz, Matthew Young and Richard Van Duyne continue the discussion of the electromagnetic-enhancement
mechanism drawing upon both computational and experimental studies.
Mark Stockman considers the electromagnetic enhancement factor by
small, properly designed nanoclusters as well as by nanostructures with fractal symmetry. George Schatz and Shengli Zou discuss the extremely high field-enhancement factors possible when plasmonic effects are coupled with photonic resonances. Mikael K¨all and Hongxing Xu present a rather complete treatment of SERS by silver-particle aggregates using generalized Mie theory, while Stefano Corni and Jacopo Tomasi apply continuum models to the study of SERS from nanoparticles and nanoparticle aggregates. Finally, Zhong-Qun Tian, Zhi-Lin Yang, Bin Ren, and De-Yin Wu discuss the observation of SERS from transition metals under ultraviolet excitation. Andreas Otto and Masayuki Futamata summarize the other large class of theories for SERS that are often referred to as the chemical mechanism as well as more generalized electronic mechanisms. Many of the chapters dealing with the electromagnetic mechanism in SERS also touch upon the broader issues of plasmonics in optical and spectroscopic contexts where the enhanced local optical fields are important independently of SERS.
Several chapters in the first section concentrate on modern experimental aspects of SERS as well as more general consequences of field enhancement. Harald and Katrin Kneipp describe the novel effects that are observable in the extremely high local optical fields produced in silver and gold nanostuctures, such as vibrational pumping and surface-enhanced hyper-Raman scattering. Enhancement of resonance Raman scattering and fluorescence by strongly coupled metallic nanostructures is the subject of the chapter by Ricardo Aroca, Paul Goulet, and Nicholas Pieczonka. Raman scattering can also be strongly enhanced in the vicinity of the sharp tips of scanning probe microscopes. Bruno Pettinger describes the development of, and recent results from tip-enhanced Raman spectroscopy (TERS). Tip-enhanced Raman spectroscopy as well as tip-enhanced CARS experiments are also discussed by Satoshi Kawata, Yasushi Inoue, and Verma Prabhat. Katrin Kneipp, Harald Kneipp and Henrik Bohr introduce single-molecule SERS spectroscopy, describing single-molecule Raman of nonresonant target molecules. Finally, Anna Rita Bizzarri and Salvatore Cannistraro consider the statistics of temporal fluctuations observed in single-molecule SERS experiments.
The second part of the book concentrates on some of the exciting applications of SERS. Single-molecule surface-enhanced resonance Raman spectroscopy and its application to green fluorescence protein is the topic of the chapter by Johan Hofkens and Satoshi Habuchi. Peter Hildebrandt and Daniel Murgida describe “surface-enhanced vibrational spectroelectrochemistry”, that is the redox and redox-coupled processes of heme proteins at an electrode surface as visualized by SERS. Janina Kneipp describes a new SERS nanosensor as an ultra-sensitive chemical probe in living cells. Adaptive plasmonic nanostructures are introduced and used for biomolecular sensing by Vladimir M. Shalaev and Vladimir P. Drachev. Another promising sensing application of SERS – glucose sensing – is described by Richard van Duyne, Chanda Ranjit Yonzon, Olga Lyandres, Nilam C. Shah, and Jon A. Dieringer. The potential for quantitative surface-enhanced resonance Raman spectroscopy as an analytical tool is presented by W. Ewen Smith, Karen Faulds, and Duncan Graham in their chapter, while the use of SERS for rapid analysis in microbiological systems is described by Royston Goodacre, Roger Jarvis, and Sarah Clarke. Tuan Vo-Dinh, Fei Yan, and Musundi B. Wabuyele discuss surface-enhanced Raman scattering as a biomedical diagnostics and molecular imaging tool. In a similar vein, Marc Porter, Hye-Young Park, Jeremy D. Driskell, Karen M. Kwarta, Robert J. Lipert, Christian Schoen, John D. Neill, and Julia F. Ridpath describe the application of SERS for carrying out ultrasensitive immunoassays using immunogold labels. Finally, Stuart Farquharson, Frank E. Inscore, and Steve Christesen report the use of SERS for detecting chemical agents and their hydrolysis products in aqueous environments.
Chanpter 1: Surface-Enhanced Raman Spectroscopy: a Brief Perspective
Chanpter 2: Electromagnetic Mechanism of SERS
Chanpter 3: Electromagnetic Theory of SERS
Chanpter 4: Coupled Plasmonic Plasmon/Photonic Resonance Effects in SERS
Chanpter 5: Estimating SERS Properties of Silver-Particle Aggregates through Generalized Mie Theory
Chanpter 6: Studying SERS from Metal Nanoparticles and Nanoparticles
Aggregates with Continuum Models
Chanpter 7: SERS From Transition Metals and Excited by Ultraviolet Light
Chanpter 8: Electronic Mechanisms of SERS
Chanpter 9: Two-Photon Excited Surface-Enhanced Raman Scattering
Chanpter 10: Applications of the Enhancement of Resonance Raman Scattering and Fluorescence by Strongly Coupled Metallic Nanostructures
Chanpter 11: Tip-Enhanced Raman Spectroscopy (TERS)
Chanpter 12: Tip-Enhanced Near-Field Raman Scattering: Fundamentals and New Aspects for Molecular Nanoanalysis/Identification
Chanpter 13: Single-Molecule SERS Spectroscopy
Chanpter 14: Temporal Fluctuations in Single-Molecule SERS Spectra
Chanpter 15: Single-Molecule Surface-Enhanced Resonance Raman Spectroscopy of the Enhanced Green Fluorescent Protein EGFP
Chanpter 16: Surface-Enhanced Vibrational Spectroelectrochemistry:
Electric-Field Effects on Redox and Redox-Coupled Processes of Heme Proteins
Chanpter 17: Nanosensors Based on SERS for Applications in Living Cells
Chanpter 18: Biomolecule Sensing with Adaptive Plasmonic Nanostructures
Chanpter 19: Glucose Sensing with Surface-Enhanced Raman Spectroscopy
Chanpter 20: Quantitative Surface-Enhanced Resonance Raman Spectroscopy for Analysis
Chanpter 21: Rapid Analysis of Microbiological Systems Using SERS
Chanpter 22: Surface-Enhanced Raman Scattering for Biomedical Diagnostics and Molecular Imaging
Chanpter 23: Ultrasensitive Immunoassays Based on Surface-Enhanced Raman Scattering by Immunogold Labels
Chanpter 24: Detecting Chemical Agents and Their Hydrolysis Products
in Water
Index
Link: http://springerlink.com/content/ ... c6d4c697b8&pi=0
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