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9783540335665

Surface-enhanced Raman Scattering

by ; ;
  • ISBN13:

    9783540335665

  • ISBN10:

    3540335668

  • Format: Hardcover
  • Copyright: 2006-09-13
  • Publisher: Springer Verlag
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Summary

Almost 30 years after the first reports on surface-enhanced Raman signals, the phenomenon of surface-enhanced Raman scattering (SERS) is now well established. Yet, explaining the enhancement of a spectroscopic signal by fouteen orders of magnitude continues to attract the attention of physicists and chemists alike. And, at the same time and rapidly growing, SERS is becoming a very useful spectroscopic tool with exciting applications in many fields. SERS gained particular interest after single-molecule Raman spectroscopy had been demonstrated. This bookl summarizes and discusses present theoretical approaches that explain the phenomenon of SERS and reports on new and exciting experiments and applications of the fascinating spectroscopic effect.

Table of Contents

Surface-Enhanced Raman Spectroscopy: a Brief Perspective
Martin Moskovits
1(18)
1 Introduction
1(1)
2 The Electromagnetic Theory of SERS
2(5)
3 Assemblies of Interacting Nanostructures: The Ubiquitous SERS-Active Systems
7(5)
4 Possible Extensions of the Electromagnetic Model
12(1)
5 Conclusions
13(1)
References
14(3)
Index
17(2)
Electromagnetic Mechanism of SERS
George C. Schatz, Matthew A. Young, Richard P. Van Duyne
19(28)
1 Introduction
19(2)
2 Electromagnetic Mechanism of SERS
21(1)
3 Numerical Methods for Calculating Electromagnetic Enhancement Factors
22(1)
4 Results of EM Calculations
23(2)
5 Long-Range Hectromagnetic Enhancement Effects
25(3)
6 Electronic-Structure Studies
28(2)
7 SERS Excitation Spectroscopy as a Probe of the Electromagnetic Mechanism
30(9)
8 Conclusions
39(1)
References
40(5)
Index
45(2)
Electromagnetic Theory of SERS
Mark I. Stockman
47(20)
1 Introduction
47(2)
2 Spectral Theory of SERS Enhancement
49(7)
2.1 Spectral Expansion of Local Fields and Green's Function
49(5)
2.2 SERS Enhancement Factor in Green's Function Theory
54(2)
3 Numerical Computations and Results
56(7)
3.1 SERS Enhancement in Fractals in Dipolar Approximation
57(1)
3.2 Single-Molecule SERS in Random Systems
58(3)
3.3 Single-Molecule SERS in Nanosphere Nanolens
61(2)
References
63(2)
Index
65(2)
Coupled Plasmonic Plasmon/Photonic Resonance Effects in SERS
Shengli Zou and George C. Schatz
67(20)
1 Introduction
67(1)
2 Methods
68(3)
3 Single Nanoparticles and Dimers
71(4)
4 Particle Arrays
75(7)
4.1 Chains Perpendicular to the Wavevector
76(3)
4.2 Chains Parallel to the Wavevector
79(2)
4.3 Configurations that Combine Parallel and Perpendicular Chains
81(1)
5 Conclusion
82(1)
References
83(2)
Index
85(2)
Estimating SERS Properties of Silver-Particle Aggregates through Generalized Mie Theory
Hongxing Xu, Mikael Käll
87(18)
1 Introduction
87(3)
1.1 Electromagnetic Enhancement
87(2)
1.2 Generalized Mie Theory
89(1)
2 The Recursive Order-of-Scattering Method
90(2)
3 Examples of GMT Calculations for Ag-Particle Aggregates
92(9)
3.1 "Hot Sites" Between Metal Particles
92(2)
3.2 Polarization Anisotropy
94(2)
3.3 Comparisons between Near-Field and Far-Field Spectra
96(2)
3.4 Including Molecular Quantum Dynamics into the EM SERS Theory
98(1)
3.5 Optical Forces
99(2)
4 Summary
101(1)
References
102(1)
Index
103(2)
Studying SERS from Metal Nanoparticles and Nanoparticles Aggregates with Continuum Models
Stefano Corni, Jacopo Tomasi
105(20)
1 Introduction
105(1)
2 Description of the Model: A Molecule Close to a Complex-Shaped Nanoparticle
106(4)
2.1 The Calculation of Surface-Enhanced Raman Spectra
107(3)
2.1.1 Enhanced Scattering Cross Section
108(2)
3 Extending the Model to Metal-Particle Aggregates
110(5)
3.1 Decomposition of the Total Enhancement
112(1)
3.2 Hot Spots and Aggregate Size
113(2)
4 Beyond SERS
115(5)
4.1 SEIRA
116(3)
4.2 Molecular Fluorescence
119(1)
5 Summary and Perspectives
120(2)
References
122(1)
Index
123(2)
SERS From Transition Metals and Excited by Ultraviolet Light
Zhong-Qun Tian, Zhi-Lin Yang, Bin Ren, De-Yin Wu
125(22)
1 Introduction
125(3)
2 The Physics behind SERS of Transition Metals
128(9)
2.1 The Electronic Structure and Dielectric Constants of Transition Metals
128(2)
2.2 Theoretical Simulation of the Local Electric Field by the Finite Difference Time-Domain Method
130(2)
2.3 3D-FDTD Simulation of the Electromagnetic Field Distribution over a Cauliflower-Like Nanostructure
132(2)
2.4 3D-FDTD Simulation of the Electromagnetic Field Distribution over a Nanocube Dimer
134(1)
2.5 3D-FDTD Simulation of Electromagnetic-Field Enhancement of Core-Shell Nanoparticles
135(2)
3 SERS From Transition Metals with Ultraviolet Excitation
137(5)
3.1 Potential-Dependent UV-Raman Spectra from Transition Metals
138(2)
3.2 Confirmation of UV-SERS Effect on Transition Metals
140(2)
4 Conclusion
142(1)
References
142(4)
Index
146(1)
Electronic Mechanisms of SERS
Andreas Otto and Masayuki Futamata
147(1)
1 Introduction
147(1)
2 Long-Range Electromagnetic (em)-Enhancement Gem and "Chemical", "First-Layer"-Enhancement Gfirst layer of Various Ag Samples
148(5)
3 The Electronic Origin of the "First-Layer Effect" of SERS
153(1)
4 The Raman-Continuum of Electron- Hole-Pair Excitations
154(3)
5 SERS-Active Sites
157(4)
6 Theory of SERS-Active Sites
161(3)
7 The Story of "Missing NO"
164(3)
8 EM Enhancement in Single-Molecule SERS of Dyes in Langmuir—Blodgett Films
167(2)
9 Conjectures on SM SERS in Junction Sites
169(3)
10 Special Examples of SERS at Low Coverage of Small Silver Aggregates
172(6)
References
178(4)
Index
182(1)
Two-Photon Excited Surface-Enhanced Raman Scattering
Katrin Kneipp, Harald Kneipp
183(14)
1 Introduction
183(1)
2 Surface-Enhanced Anti-Stokes Raman Scattering
184(6)
2.1 SERS Vibrational Pumping
184(4)
2.2 Pumped Anti-Stokes SERS — A Two-Photon Raman Effect
188(2)
3 Surface-Enhanced Hyper-Raman Scattering (SEHRS)
190(3)
3.1 SEHRS Enhancement Factors
190(1)
3.2 Resonant and Nonresonant Surface-Enhanced Hyper-Raman Scattering
191(2)
4 Summary and Conclusion
193(1)
References
194(2)
Index
196(1)
Applications of the Enhancement of Resonance Raman Scattering and Fluorescence by Strongly Coupled Metallic Nanostructures
Nicholas P.W. Pieczonka, Paul J.G. Goulet, Ricardo F. Aroca
197(20)
1 Introduction
197(4)
2 Applications
201(12)
2.1 SERRS of Thin Solid Films and Langmuir—Blodgett Monolayers
201(5)
2.1.1 Spatial Spectroscopic Tuning
203(1)
2.1.2 SERRS Mapping and Imaging
204(2)
2.1.3 Single-Molecule SERRS from Langmuir—Blodgett Monolayers
206(1)
2.2 SERRS from Colloids and Nanocomposite Films
206(6)
2.2.1 SERRS from Ag and Au Metal Colloids
208(2)
2.2.2 SERRS from Silver Nanowire Layer-by-Layer Film Substrates
210(2)
2.3 SEF of LB
212(1)
3 Conclusion
213(1)
References
214(2)
Index
216(1)
Tip-Enhanced Raman Spectroscopy (TERS)
Bruno Pettinger
217(24)
1 Introduction
217(3)
2 TERS Results
220(17)
2.1 Remarks on SERRS
220(1)
2.2 Initial Steps in TERS
221(8)
2.3 Towards Higher Efficiencies in TERS
229(8)
3 Conclusion/Outlook
237(1)
References
238(2)
Index
240(1)
Tip-Enhanced Near-Field Raman Scattering: Fundamentals and New Aspects for Molecular Nanoanalysis/Identification
Prabhat Verma, Yasushi Inouye, Satoshi Kawata
241(20)
1 Introduction
241(1)
2 Localized Surface-Plasmon Polaritons at the Tip
241(1)
3 Instrumentation
242(1)
4 TERS from Single-Wall Carbon Nanotube
243(4)
5 TERS Measurements on Rhodamine 6G
247(3)
6 Tip Force on DNA-Based Adenine Molecules
250(3)
6.1 TERS from Adenine
250(1)
6.2 TERS from Tip-Pressurized Adenine Molecules
251(2)
7 Tip-Enhanced Coherent Anti-Stokes Raman Scattering
253(6)
References
259(1)
Index
260(1)
Single-Molecule SERS Spectroscopy
Katrin Kneipp, Harald Kneipp, Henrik G. Bohr
261(18)
1 Introduction
261(2)
2 Single-Molecule SERS Experiments
263(7)
2.1 Single-Molecule SERS on Silver and Gold Nanoclusters in Solution
264(3)
2.2 Single-Molecule SERS on Fixed Fractal Silver and Gold Cluster Structures
267(3)
3 SERS as a Single-Molecule Analytical Tool – Comparison between SERS and Fluorescence
270(3)
3.1 Potential Applications of Single-Molecule Raman Spectroscopy
271(2)
4 Conclusion
273(1)
References
274(3)
Index
277(2)
Temporal Fluctuations in Single-Molecule SERS Spectra
Anna Rita Bizzarri, Salvatore Cannistraro
279(18)
1 Introduction
279(1)
2 Materials and Methods
280(2)
3 Results and Discussion
282(11)
3.1 Fluctuations in SM SERS Spectra
282(1)
3.2 Statistical Analysis of Intensity Fluctuations in SM SERS Spectra
283(4)
3.3 ET in SM SERS Spectra of FePP
287(3)
3.4 Levy Statistics in SM SERS Spectra of FePP
290(3)
4 Conclusions and Perspectives
293(1)
References
293(3)
Index
296(1)
Single-Molecule Surface-Enhanced Resonance Raman Spectroscopy of the Enhanced Green Fluorescent Protein EGFP
Satoshi Habuchi, Johan Hofkens
297(16)
1 Introduction
297(1)
2 Experimental Section
298(2)
2.1 Purification of EGFP
298(1)
2.2 Sample Preparation for SM-SERRS Measurements
298(1)
2.3 Experimental Setup
298(1)
2.4 Autocorrelation Analysis
299(1)
3 Results and Discussion
300(10)
3.1 Single EGFP Molecules Detected by SERRS
300(1)
3.2 SM-SERRS Spectra of EGFP
301(4)
3.3 Discussion on the Spectral Jumps Observed in the SM-SERRS Spectra of EGFP
305(1)
3.4 The Relation between the Fluorescence and SERRS Intensity Trajectories of EGFP
306(4)
4 Summary
310(1)
References
310(2)
Index
312(1)
Surface-Enhanced Vibrational Spectroelectrochemistry: Electric-Field Effects on Redox and Redox-Coupled Processes of Heme Proteins
Daniel Murgida, Peter Hildebrandt
313(22)
1 Introduction
313(1)
2 Strategy and Methodological Approach
314(7)
2.1 Protein Immobilization on SER/SEIRA Active Metal Electrodes
314(2)
2.2 Surface-Enhanced Vibrational Spectroelectrochemistry of Heme Proteins
316(3)
2.3 Theoretical Description and Experimental Determination of the Electric-Field
319(2)
3 Electric-Field Effects on the Interfacial Processes of Heme Proteins
321(10)
3.1 Conformational Changes of Cytochrome c
321(2)
3.2 Modulation of Redox Potentials
323(2)
3.3 Electron-Transfer Dynamics of Cytochrome c and Other Soluble Electron Carriers
325(2)
3.4 Electric-Field Effects on the Electroprotonic Energy Transduction of Heme-Cu Oxidases
327(4)
4 Concluding Remarks
331(1)
References
332(2)
Index
334(1)
Nanosensors Based on SERS for Applications in Living Cells
Janina Kneipp
335(16)
1 Reasons for Intracellular SERS Approaches
335(3)
1.1 Raman Spectra from Biological Samples
335(1)
1.2 Advantages of SERS for Studies in Cells
336(2)
2 SERS Nanosensors for Probing of Intrinsic Cellular Chemistry
338(4)
2.1 Requirements of Cellular Systems
338(1)
2.2 SERS Nanosensors in Endosomal Structures
338(3)
2.3 Gold Nanoparticles and the Cellular Environment
341(1)
3 A Labeled Nanosensor Based on the SERS Signal of Indocyanine Green
342(3)
3.1 Characterization of the SERS Label
342(1)
3.2 Application of ICG-SERS Nanoprobes in Living Cells
343(2)
4 Conclusions and Outlook
345(3)
References
348(1)
Index
349(2)
Biomolecule Sensing with Adaptive Plasmonic Nanostructures
Vladimir P. Drachev, Vladimir M. Shalaev
351(16)
1 Introduction
351(1)
2 Adaptive Plasmonic Nanostructures
352(2)
3 SERS Features of Conformational States: Insulin
354(4)
3.1 SERS Versus Normal Raman
355(2)
3.2 Human Insulin Versus Insulin Lispro
357(1)
4 Ebola Virus after Pseudotyping
358(1)
5 Tag-Free Antibody—Antigen Binding Detection
359(3)
6 Protein-Binding Detection with Dye Displacement
362(1)
7 Summary
363(1)
References
364(2)
Index
366(1)
Glucose Sensing with Surface-Enhanced Raman Spectroscopy
Chanda Ranjit Yonzon, Olga Lyandres, Nilam C. Shah, Jon A. Dieringer, Richard P. Van Duyne
367(14)
1 Introduction
367(3)
2 SERS of Glucose
370(1)
3 Reversibility and Real-Time Glucose Sensing
371(3)
4 Quantitative Aspects of Glucose Sensing with SERS
374(2)
5 Temporal Stability of the SERS Glucose Sensor
376(1)
6 Conclusions
376(1)
References
377(2)
Index
379(2)
Quantitative Surface-Enhanced Resonance Raman Spectroscopy for Analysis
W.E. Smith, K. Faulds, and D. Graham
381(16)
1 Introduction
381(2)
2 Experimental Approach
383(6)
2.1 Choice of Wavelength
383(2)
2.2 Types of Assay
385(1)
2.3 Choice of Analytes
386(2)
2.4 Choice of Substrates
388(1)
3 Examples of Analytical Methods
389(5)
3.1 DNA
389(3)
3.2 Mitoxantrone
392(1)
3.3 Drugs of Abuse
393(1)
3.4 Glucose
393(1)
3.5 Derivatization Assays
393(1)
4 Analysis Using Individual Nanoparticles
394(1)
5 Summary
395(1)
References
395(1)
Index
396(1)
Rapid Analysis of Microbiological Systems Using SERS
Roger Jarvis, Sarah Clarke, Royston Goodacre
397(12)
1 Introduction
397(1)
2 Spectroscopic Characterization of Micro-Organisms
398(2)
3 Introduction to Multivariate Cluster Analysis
400(2)
4 Identification of Micro-Organisms Using SERS
402(1)
5 Monitoring Industrial Bioprocesses
403(1)
6 Gene-Function Analysis
404(2)
7 Concluding Remarks
406(1)
References
406(2)
Index
408(1)
Surface-Enhanced Raman Scattering for Biomedical Diagnostics and Molecular Imaging
Tuan Vo-Dinh, Fei Yam Musundi B. Wabuyele
409(18)
1 Introduction
409(1)
2 Methods and Instrumentation
410(4)
2.1 Silver Nanoparticle Island Films for Biomedical Diagnostics
410(2)
2.2 Silver Nanoparticles for Cellular Imaging
412(1)
2.3 SERS Instrumentation
413(1)
3 SERS Applications
414(9)
3.1 SERS Gene Probe for Medical Diagnostics
414(3)
3.2 Hyperspectral Imaging of Raman Dye-Labeled Silver Nanoparticles in Single Cells
417(1)
3.3 SERS Near-Field Scanning Optical Microscopy (SERS-NSOM)
418(3)
3.4 SERS Molecular Sentinels
421(2)
4 Conclusion
423(2)
References
425(1)
Index
426(1)
Ultrasensitive Immunoassays Based on Surface-Enhanced Raman Scattering by Immunogold Labels
Hye-Young Park, Jeremy D. Driskell, Karen M. Kwarta, Robert J. Lipert, Marc D. Porter, Christian Schoen, John D. Neill, Julia F. Ridpath
427(20)
1 Introduction
427(2)
2 Assay Design
429(5)
2.1 Preparation of Capture Antibody Substrates
429(2)
2.2 ERL Preparation
431(2)
2.3 Immunoassay Protocols
433(1)
3 Spectroscopic Instrumentation
434(1)
4 Maximization of Signal Strength
434(3)
5 Assays
437(3)
5.1 Early Disease Detection
437(2)
5.2 Assay of Erwinia Herbicola (BW Stimulant)
439(1)
6 Showcasing Performance
440(3)
6.1 Single E. coli 0157:H7 SERS
440(1)
6.2 Assay of PPV
441(2)
7 Conclusions
443(1)
References
444(2)
Index
446(1)
Detecting Chemical Agents and Their Hydrolysis Products in Water
Stuart Farquharson, Frank E. Inscore, Steve Christesen
447(14)
1 Introduction
447(1)
2 Experimental
448(1)
3 Results and Discussion
449(8)
3.1 Cyanide
449(2)
3.2 HD and GEES
451(3)
3.3 GB
454(1)
3.4 VX
455(2)
4 Conclusions
457(1)
References
458(2)
Index
460(1)
Index 461

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