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100   $a20140324h20142014  uy             0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 00$aFrontiers of surface-enhanced raman scattering $esingle-nanoparticles and single cells /$fedited by Yukihiro Ozaki, Katrin Kneipp, Ricardo R Aroca
210  1$aChichester, England :$cWiley,$d2014.
210  4$dİ2014
215   $a1 online resource (367 p.)
300   $aIncludes index.
311   $a1-118-35902-X 
320   $aIncludes bibliographical references at the end of each chapters and index.
327   $aCover; Title Page; Copyright; Contents; List of Contributors; Preface; Chapter 1 Calculation of Surface-Enhanced Raman Spectra Including Orientational and Stokes Effects Using TDDFT/Mie Theory QM/ED Method; 1.1 Introduction: Combined Quantum Mechanics/ Electrodynamics Methods; 1.2 Computational Details; 1.3 Summary of Model Systems; 1.4 Azimuthal Averaging; 1.5 SERS of Pyridine: Models G, A, B, S, and V; 1.6 Orientation Effects in SERS of Phthalocyanines; 1.7 Two Particle QM/ED Calculations; 1.8 Summary; Acknowledgment; References
327   $aChapter 2 Non-resonant SERS Using the Hottest Hot Spots of Plasmonic Nanoaggregates2.1 Introduction; 2.2 Aggregates of Silver and Gold Nanoparticles and Their Hot Spots; 2.2.1 Evaluation of Plasmonic Nanoaggregates by Vibrational Pumping due to a Non-resonant SERS Process; 2.2.2 Probing Plasmonic Nanoaggregates by Electron Energy Loss Spectroscopy; 2.2.3 Probing Local Fields in Hot Spots by SERS and SEHRS; 2.3 SERS Using Hot Silver Nanoaggregates and Non-resonant NIR Excitation; 2.3.1 SERS Signal vs. Concentration of the Target Molecule
327   $a2.3.2 Spectroscopic Potential of Non-resonant SERS Using the Hottest Hot Spots2.4 Summary and Conclusions; References; Chapter 3 Effect of Nanoparticle Symmetry on Plasmonic Fields: Implications for Single-Molecule Raman Scattering; 3.1 Introduction; 3.2 Methodology; 3.3 Plasmon Mode Structure of Nanoparticle Clusters; 3.3.1 Dimers; 3.3.2 Trimers; 3.4 Effect of Plasmon Modes on SMSERS; 3.4.1 Effect of the Spectral Lineshape; 3.4.2 Effect of Multiple Normal Modes; 3.5 Conclusions; Acknowledgment; References
327   $aChapter 4 Experimental Demonstration of Electromagnetic Mechanism of SERS and Quantitative Analysis of SERS Fluctuation Based on the Mechanism4.1 Experimental Demonstration of the EM Mechanism of SERS; 4.1.1 Introduction; 4.1.2 Observations of the EM Mechanism in SERS Spectral Variations; 4.1.3 Observations of the EM Mechanism in the Refractive Index Dependence of SERS Spectra; 4.1.4 Quantitative Evaluation of the EM Mechanism of SERS; 4.1.5 Summary; 4.2 Quantitative Analysis of SERS Fluctuation Based on the EM Mechanism; 4.2.1 Introduction
327   $a4.2.2 Intensity and Spectral Fluctuation in SERS and SEF4.2.3 Framework for Analysis of Fluctuation in SERS and SEF; 4.2.4 Analysis of Intensity Fluctuation in SERS and SEF; 4.2.5 Analysis of Spectral Fluctuation in SERS and SEF; 4.2.6 Summary; 4.3 Conclusion; Acknowledgments; References; Chapter 5 Single-Molecule Surface-Enhanced Raman Scattering as a Probe for Adsorption Dynamics on Metal Surfaces; 5.1 Introduction; 5.2 Simultaneous Measurements of Conductance and SERS of a Single-Molecule Junction; 5.3 SERS Observation Using Heterometallic Nanodimers at the Single-Molecule Level
327   $a5.4 Conclusion
330   $a A comprehensive presentation of Surface-Enhanced Raman Scattering (SERS) theory, substrate fabrication, applications of SERS to biosystems, chemical analysis, sensing and fundamental innovation through experimentation. Written by internationally recognized editors and contributors. Relevant to all those within the scientific community dealing with Raman Spectroscopy, i.e. physicists, chemists, biologists, material scientists, physicians and biomedical scientists. SERS applications are widely expanding and the technology is now used in the field of nanotechnologies, a
606   $aRaman effect, Surface enhanced
606   $aSurfaces (Physics)
606   $aRaman spectroscopy
606   $aSpectrum analysis
615  0$aRaman effect, Surface enhanced.
615  0$aSurfaces (Physics)
615  0$aRaman spectroscopy.
615  0$aSpectrum analysis.
676   $a543/.57
702   $aOzaki$b Y$g(Yukihiro),
702   $aKneipp$b Katrin
702   $aAroca$b Ricardo
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910140286103321
996   $aFrontiers of surface-enhanced raman scattering$92279513
997   $aUNINA