Nikhil Ranjan Jana
An Overall Account of Surface Enhanced Raman Spectroscopy
Nikhil Ranjan Jana
An Overall Account of Surface Enhanced Raman Spectroscopy
- Gebundenes Buch
- Merkliste
- Auf die Merkliste
- Bewerten Bewerten
- Teilen
- Produkt teilen
- Produkterinnerung
- Produkterinnerung
This book covers all the aspects of surface enhanced Raman Spectroscopy (SERS) including brief history of the discovery of SERS and development of the field, basic principles and enhancement mechanism of SERS.
Andere Kunden interessierten sich auch für
- Surface Enhanced Raman Scattering - Sers220,99 €
- Charles L. Wilkins (ed.)Computer-Enhanced Analytical Spectroscopy Volume 4115,99 €
- Computer-Enhanced Analytical Spectroscopy39,99 €
- Peter C. Jurs (Hrsg.)Computer-Enhanced Analytical Spectroscopy Volume 3153,99 €
- Computer-Enhanced Analytical Spectroscopy39,99 €
- Dr.Amare Ayalew AbebeConfiscation of aromatic compounds. Microwave synthesized electrolyte treated and Si/Al enhanced mesoporous zeolitic materials originated from sugar industry detritus47,95 €
- Laser-Enhanced Ionization Spectroscopy230,99 €
-
-
-
This book covers all the aspects of surface enhanced Raman Spectroscopy (SERS) including brief history of the discovery of SERS and development of the field, basic principles and enhancement mechanism of SERS.
Produktdetails
- Produktdetails
- Verlag: Taylor & Francis Ltd
- Seitenzahl: 192
- Erscheinungstermin: 24. Juni 2025
- Englisch
- Abmessung: 216mm x 138mm
- Gewicht: 453g
- ISBN-13: 9781032622897
- ISBN-10: 103262289X
- Artikelnr.: 73778861
- Herstellerkennzeichnung
- Libri GmbH
- Europaallee 1
- 36244 Bad Hersfeld
- gpsr@libri.de
- Verlag: Taylor & Francis Ltd
- Seitenzahl: 192
- Erscheinungstermin: 24. Juni 2025
- Englisch
- Abmessung: 216mm x 138mm
- Gewicht: 453g
- ISBN-13: 9781032622897
- ISBN-10: 103262289X
- Artikelnr.: 73778861
- Herstellerkennzeichnung
- Libri GmbH
- Europaallee 1
- 36244 Bad Hersfeld
- gpsr@libri.de
Nikhil R. Jana is a Professor at the School of Materials Science, Indian Association for the Cultivation of Science, Kolkata, India. He received his undergraduate degree (1987) from Midnapore College and Masters (1989) and PhD degree (1994) from Indian Institute of Technology, Kharagpur. He has worked as a postdoctoral fellow at the University of South Carolina-USA (1999¿2001) and University of Arkansas-USA (2003) and Scientist at the Institute of Bioengineering and Nanotechnology-Singapore (2004-2008). His research group designs colloidal nanobioconjugate for controlling cellular processes, develops nanoprobes/nanodrugs for sub-cellular targeting/imaging and investigates colloidal nanodrugs for therapeutic applications. His group has published 220 peer-reviewed research articles in internationally recognized journals, which have about 30,000 citations. He has been serving as an Associate Editor of ACS Applied Nano Materials since 2019.
Chapter 1. A brief history of the discovery and development of surface
enhanced Raman scattering. 1.1 Introduction. 1.2 Discovery and development.
1.3 Multidisciplinary and interdisciplinary nature of SERS effect. 1.4
Other variants of SERS. 1.5 Signal reproducibility issue. 1.6 Conclusion.
References. Chapter 2. Basic principle and enhancement mechanisms for SERS.
2.1 Role of plasmonic nanostructures in SERS. 2.2 Electromagnetic
enhancement mechanism. 2.3 Chemical enhancement mechanism. 2.4 Enhancement
factor. 2.5 Selection rule. 2.6 Conclusion. References. Chapter 3.
Plasmonic nanomaterials: First generation SERS substrates. 3.1
Introduction. 3.2 Plasmonic nanoparticles and colloids. 3.3 Plasmonic thin
films. 3.4 Plasmonic 3D materials. 3.5 Conclusions. References. Chapter 4.
Plasmonic nanostructures with electromagnetic hot spots: Second generation
SERS substrates. 4.1 Introduction. 4.2 Controlled aggregation of colloidal
nanoparticles. 4.3 Plasmonic nanorod, nanostar, triangle, nanoshell and
other anisotropic shapes. 4.4 Plasmonic nanoparticle dimers and oligomers.
4.5 2D array and 3D superlattice. 4.6 Conclusions. References. Chapter 5.
Plasmonic hot spot engineering: Third generation SERS substrates. 5.1
Introduction. 5.2 Individual plasmonic nanoparticle on a flat metal film as
SERS substrates. 5.3 Plasmonic nanoparticles with an ultrathin shell as
universal SERS substrates. 5.4 Plasmonic tip-enhanced SERS. 5.5
Graphene-enhanced SERS. 5.6 Piezoelectric material-based SERS enhancement.
5.7 Pyroelectric/thermoelectric material-based SERS enhancement. 5.8
Superhydrophobic platform-based SERS enhancement. 5.9 Conclusion.
References. Chapter 6. SERS-based detection platforms and signal
reproducibility issues. 6.1 Introduction. 6.2 Instrumentation. 6.3 SERS
detection platforms. 6.4 Raman probe. 6.5 Origin of poor signal
reproducibility and possible solutions. 6.6 Conclusion. References. Chapter
7. SERS-based single molecule detection. 7.1 Discovery and development of
single molecule SERS. 7.2 Verification of single molecule SERS. 7.3 Nanogap
engineering and molecular localization at electromagnetic hot spot for
single molecule SERS. 7.4 Designed substrate for single molecule SERS. 7.5
Application of single molecule SERS. 7.6 Conclusion. References. Chapter 8.
Designed SERS probes for detection application with improved signal
reproducibility. 8.1 Introduction. 8.2 Molecular Raman reporter coated
plasmonic nanoparticle as SERS probe. 8.3 SERS-based detection via
molecular analyte-mediated assembly of plasmonic nanoparticle. 8.4
SERS-based detection via molecular analyte-mediated plasmonic nanoparticle
dimer formation. 8.5 SERS-based detection via engineering-based plasmonic
hot spot generation. 8.6 Other engineering approaches for SERS-based
detection. 8.7 Conclusion. References. Chapter 9. Chemical analysis by
SERS. 9.1 Introduction. 9.2 Quantitative detection application. 9.3
Environmental monitoring. 9.4 SERS in forensic science. 9.5 Identification
of catalytic intermediates. 9.6 Enantioselective discrimination of chiral
molecules. 9.7 Conclusion. References. Chapter 10. Biomedical applications
of SERS. 10.1 Introduction. 10.2 Bioassays. 10.3 Detection of pathogens.
10.4 Detection of cells and cellular biochemicals. 10.5 Bioimaging. 10.6
Conclusion. References. Chapter 11. Outlook and future of SERS. 11.1
Introduction. 11.2 Advancement in SERS substrate fabrication. 11.3
Challenges on quantitative SERS with high sensitivity. 11.4 Temporal and
spatial resolution limits in SERS. 11.5 Coupling SERS with other platforms.
11.6 Machine learning and SERS. 11.7 Conclusion. References
enhanced Raman scattering. 1.1 Introduction. 1.2 Discovery and development.
1.3 Multidisciplinary and interdisciplinary nature of SERS effect. 1.4
Other variants of SERS. 1.5 Signal reproducibility issue. 1.6 Conclusion.
References. Chapter 2. Basic principle and enhancement mechanisms for SERS.
2.1 Role of plasmonic nanostructures in SERS. 2.2 Electromagnetic
enhancement mechanism. 2.3 Chemical enhancement mechanism. 2.4 Enhancement
factor. 2.5 Selection rule. 2.6 Conclusion. References. Chapter 3.
Plasmonic nanomaterials: First generation SERS substrates. 3.1
Introduction. 3.2 Plasmonic nanoparticles and colloids. 3.3 Plasmonic thin
films. 3.4 Plasmonic 3D materials. 3.5 Conclusions. References. Chapter 4.
Plasmonic nanostructures with electromagnetic hot spots: Second generation
SERS substrates. 4.1 Introduction. 4.2 Controlled aggregation of colloidal
nanoparticles. 4.3 Plasmonic nanorod, nanostar, triangle, nanoshell and
other anisotropic shapes. 4.4 Plasmonic nanoparticle dimers and oligomers.
4.5 2D array and 3D superlattice. 4.6 Conclusions. References. Chapter 5.
Plasmonic hot spot engineering: Third generation SERS substrates. 5.1
Introduction. 5.2 Individual plasmonic nanoparticle on a flat metal film as
SERS substrates. 5.3 Plasmonic nanoparticles with an ultrathin shell as
universal SERS substrates. 5.4 Plasmonic tip-enhanced SERS. 5.5
Graphene-enhanced SERS. 5.6 Piezoelectric material-based SERS enhancement.
5.7 Pyroelectric/thermoelectric material-based SERS enhancement. 5.8
Superhydrophobic platform-based SERS enhancement. 5.9 Conclusion.
References. Chapter 6. SERS-based detection platforms and signal
reproducibility issues. 6.1 Introduction. 6.2 Instrumentation. 6.3 SERS
detection platforms. 6.4 Raman probe. 6.5 Origin of poor signal
reproducibility and possible solutions. 6.6 Conclusion. References. Chapter
7. SERS-based single molecule detection. 7.1 Discovery and development of
single molecule SERS. 7.2 Verification of single molecule SERS. 7.3 Nanogap
engineering and molecular localization at electromagnetic hot spot for
single molecule SERS. 7.4 Designed substrate for single molecule SERS. 7.5
Application of single molecule SERS. 7.6 Conclusion. References. Chapter 8.
Designed SERS probes for detection application with improved signal
reproducibility. 8.1 Introduction. 8.2 Molecular Raman reporter coated
plasmonic nanoparticle as SERS probe. 8.3 SERS-based detection via
molecular analyte-mediated assembly of plasmonic nanoparticle. 8.4
SERS-based detection via molecular analyte-mediated plasmonic nanoparticle
dimer formation. 8.5 SERS-based detection via engineering-based plasmonic
hot spot generation. 8.6 Other engineering approaches for SERS-based
detection. 8.7 Conclusion. References. Chapter 9. Chemical analysis by
SERS. 9.1 Introduction. 9.2 Quantitative detection application. 9.3
Environmental monitoring. 9.4 SERS in forensic science. 9.5 Identification
of catalytic intermediates. 9.6 Enantioselective discrimination of chiral
molecules. 9.7 Conclusion. References. Chapter 10. Biomedical applications
of SERS. 10.1 Introduction. 10.2 Bioassays. 10.3 Detection of pathogens.
10.4 Detection of cells and cellular biochemicals. 10.5 Bioimaging. 10.6
Conclusion. References. Chapter 11. Outlook and future of SERS. 11.1
Introduction. 11.2 Advancement in SERS substrate fabrication. 11.3
Challenges on quantitative SERS with high sensitivity. 11.4 Temporal and
spatial resolution limits in SERS. 11.5 Coupling SERS with other platforms.
11.6 Machine learning and SERS. 11.7 Conclusion. References
Chapter 1. A brief history of the discovery and development of surface
enhanced Raman scattering. 1.1 Introduction. 1.2 Discovery and development.
1.3 Multidisciplinary and interdisciplinary nature of SERS effect. 1.4
Other variants of SERS. 1.5 Signal reproducibility issue. 1.6 Conclusion.
References. Chapter 2. Basic principle and enhancement mechanisms for SERS.
2.1 Role of plasmonic nanostructures in SERS. 2.2 Electromagnetic
enhancement mechanism. 2.3 Chemical enhancement mechanism. 2.4 Enhancement
factor. 2.5 Selection rule. 2.6 Conclusion. References. Chapter 3.
Plasmonic nanomaterials: First generation SERS substrates. 3.1
Introduction. 3.2 Plasmonic nanoparticles and colloids. 3.3 Plasmonic thin
films. 3.4 Plasmonic 3D materials. 3.5 Conclusions. References. Chapter 4.
Plasmonic nanostructures with electromagnetic hot spots: Second generation
SERS substrates. 4.1 Introduction. 4.2 Controlled aggregation of colloidal
nanoparticles. 4.3 Plasmonic nanorod, nanostar, triangle, nanoshell and
other anisotropic shapes. 4.4 Plasmonic nanoparticle dimers and oligomers.
4.5 2D array and 3D superlattice. 4.6 Conclusions. References. Chapter 5.
Plasmonic hot spot engineering: Third generation SERS substrates. 5.1
Introduction. 5.2 Individual plasmonic nanoparticle on a flat metal film as
SERS substrates. 5.3 Plasmonic nanoparticles with an ultrathin shell as
universal SERS substrates. 5.4 Plasmonic tip-enhanced SERS. 5.5
Graphene-enhanced SERS. 5.6 Piezoelectric material-based SERS enhancement.
5.7 Pyroelectric/thermoelectric material-based SERS enhancement. 5.8
Superhydrophobic platform-based SERS enhancement. 5.9 Conclusion.
References. Chapter 6. SERS-based detection platforms and signal
reproducibility issues. 6.1 Introduction. 6.2 Instrumentation. 6.3 SERS
detection platforms. 6.4 Raman probe. 6.5 Origin of poor signal
reproducibility and possible solutions. 6.6 Conclusion. References. Chapter
7. SERS-based single molecule detection. 7.1 Discovery and development of
single molecule SERS. 7.2 Verification of single molecule SERS. 7.3 Nanogap
engineering and molecular localization at electromagnetic hot spot for
single molecule SERS. 7.4 Designed substrate for single molecule SERS. 7.5
Application of single molecule SERS. 7.6 Conclusion. References. Chapter 8.
Designed SERS probes for detection application with improved signal
reproducibility. 8.1 Introduction. 8.2 Molecular Raman reporter coated
plasmonic nanoparticle as SERS probe. 8.3 SERS-based detection via
molecular analyte-mediated assembly of plasmonic nanoparticle. 8.4
SERS-based detection via molecular analyte-mediated plasmonic nanoparticle
dimer formation. 8.5 SERS-based detection via engineering-based plasmonic
hot spot generation. 8.6 Other engineering approaches for SERS-based
detection. 8.7 Conclusion. References. Chapter 9. Chemical analysis by
SERS. 9.1 Introduction. 9.2 Quantitative detection application. 9.3
Environmental monitoring. 9.4 SERS in forensic science. 9.5 Identification
of catalytic intermediates. 9.6 Enantioselective discrimination of chiral
molecules. 9.7 Conclusion. References. Chapter 10. Biomedical applications
of SERS. 10.1 Introduction. 10.2 Bioassays. 10.3 Detection of pathogens.
10.4 Detection of cells and cellular biochemicals. 10.5 Bioimaging. 10.6
Conclusion. References. Chapter 11. Outlook and future of SERS. 11.1
Introduction. 11.2 Advancement in SERS substrate fabrication. 11.3
Challenges on quantitative SERS with high sensitivity. 11.4 Temporal and
spatial resolution limits in SERS. 11.5 Coupling SERS with other platforms.
11.6 Machine learning and SERS. 11.7 Conclusion. References
enhanced Raman scattering. 1.1 Introduction. 1.2 Discovery and development.
1.3 Multidisciplinary and interdisciplinary nature of SERS effect. 1.4
Other variants of SERS. 1.5 Signal reproducibility issue. 1.6 Conclusion.
References. Chapter 2. Basic principle and enhancement mechanisms for SERS.
2.1 Role of plasmonic nanostructures in SERS. 2.2 Electromagnetic
enhancement mechanism. 2.3 Chemical enhancement mechanism. 2.4 Enhancement
factor. 2.5 Selection rule. 2.6 Conclusion. References. Chapter 3.
Plasmonic nanomaterials: First generation SERS substrates. 3.1
Introduction. 3.2 Plasmonic nanoparticles and colloids. 3.3 Plasmonic thin
films. 3.4 Plasmonic 3D materials. 3.5 Conclusions. References. Chapter 4.
Plasmonic nanostructures with electromagnetic hot spots: Second generation
SERS substrates. 4.1 Introduction. 4.2 Controlled aggregation of colloidal
nanoparticles. 4.3 Plasmonic nanorod, nanostar, triangle, nanoshell and
other anisotropic shapes. 4.4 Plasmonic nanoparticle dimers and oligomers.
4.5 2D array and 3D superlattice. 4.6 Conclusions. References. Chapter 5.
Plasmonic hot spot engineering: Third generation SERS substrates. 5.1
Introduction. 5.2 Individual plasmonic nanoparticle on a flat metal film as
SERS substrates. 5.3 Plasmonic nanoparticles with an ultrathin shell as
universal SERS substrates. 5.4 Plasmonic tip-enhanced SERS. 5.5
Graphene-enhanced SERS. 5.6 Piezoelectric material-based SERS enhancement.
5.7 Pyroelectric/thermoelectric material-based SERS enhancement. 5.8
Superhydrophobic platform-based SERS enhancement. 5.9 Conclusion.
References. Chapter 6. SERS-based detection platforms and signal
reproducibility issues. 6.1 Introduction. 6.2 Instrumentation. 6.3 SERS
detection platforms. 6.4 Raman probe. 6.5 Origin of poor signal
reproducibility and possible solutions. 6.6 Conclusion. References. Chapter
7. SERS-based single molecule detection. 7.1 Discovery and development of
single molecule SERS. 7.2 Verification of single molecule SERS. 7.3 Nanogap
engineering and molecular localization at electromagnetic hot spot for
single molecule SERS. 7.4 Designed substrate for single molecule SERS. 7.5
Application of single molecule SERS. 7.6 Conclusion. References. Chapter 8.
Designed SERS probes for detection application with improved signal
reproducibility. 8.1 Introduction. 8.2 Molecular Raman reporter coated
plasmonic nanoparticle as SERS probe. 8.3 SERS-based detection via
molecular analyte-mediated assembly of plasmonic nanoparticle. 8.4
SERS-based detection via molecular analyte-mediated plasmonic nanoparticle
dimer formation. 8.5 SERS-based detection via engineering-based plasmonic
hot spot generation. 8.6 Other engineering approaches for SERS-based
detection. 8.7 Conclusion. References. Chapter 9. Chemical analysis by
SERS. 9.1 Introduction. 9.2 Quantitative detection application. 9.3
Environmental monitoring. 9.4 SERS in forensic science. 9.5 Identification
of catalytic intermediates. 9.6 Enantioselective discrimination of chiral
molecules. 9.7 Conclusion. References. Chapter 10. Biomedical applications
of SERS. 10.1 Introduction. 10.2 Bioassays. 10.3 Detection of pathogens.
10.4 Detection of cells and cellular biochemicals. 10.5 Bioimaging. 10.6
Conclusion. References. Chapter 11. Outlook and future of SERS. 11.1
Introduction. 11.2 Advancement in SERS substrate fabrication. 11.3
Challenges on quantitative SERS with high sensitivity. 11.4 Temporal and
spatial resolution limits in SERS. 11.5 Coupling SERS with other platforms.
11.6 Machine learning and SERS. 11.7 Conclusion. References