Isao Noda, Yukihiro Ozaki
Two-Dimensional Correlation Spectroscopy
Applications in Vibrational and Optical Spectroscopy
Isao Noda, Yukihiro Ozaki
Two-Dimensional Correlation Spectroscopy
Applications in Vibrational and Optical Spectroscopy
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Previously available only in papers and reviews, the work of these prominent authors have done in 2D optical and vibrational spectroscopy (IR, Raman, UV, Visible) is now in one volume. Their work is particularly useful for the analysis of large molecules such as polymers, as these often cannot be analyzed by normal spectroscopy.
A valuable tool for individuals using correlation spectroscopy and those that want to start using this technique. Noda is known as the founder of this technique, and together with Ozaki, they are the two biggest names in the area _ First book on 2D vibrational and…mehr
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Previously available only in papers and reviews, the work of these prominent authors have done in 2D optical and vibrational spectroscopy (IR, Raman, UV, Visible) is now in one volume. Their work is particularly useful for the analysis of large molecules such as polymers, as these often cannot be analyzed by normal spectroscopy.
A valuable tool for individuals using correlation spectroscopy and those that want to start using this technique. Noda is known as the founder of this technique, and together with Ozaki, they are the two biggest names in the area
_ First book on 2D vibrational and optical spectroscopy - single source of information, pulling together literature papers and reveiws
_ Growing number of applications of this methodology - book now needed for people thinking of using this technique
_ Limitations and benefits discussed and comparisons made with 2D NMR
_ Discusses 20 optical and vibrational spectroscopy (IR, Raman, UV, Visible)
A valuable tool for individuals using correlation spectroscopy and those that want to start using this technique. Noda is known as the founder of this technique, and together with Ozaki, they are the two biggest names in the area
_ First book on 2D vibrational and optical spectroscopy - single source of information, pulling together literature papers and reveiws
_ Growing number of applications of this methodology - book now needed for people thinking of using this technique
_ Limitations and benefits discussed and comparisons made with 2D NMR
_ Discusses 20 optical and vibrational spectroscopy (IR, Raman, UV, Visible)
Produktdetails
- Produktdetails
- Verlag: Wiley & Sons
- 1. Auflage
- Seitenzahl: 312
- Erscheinungstermin: 29. Oktober 2004
- Englisch
- Abmessung: 235mm x 159mm x 24mm
- Gewicht: 570g
- ISBN-13: 9780471623915
- ISBN-10: 0471623911
- Artikelnr.: 13066440
- Verlag: Wiley & Sons
- 1. Auflage
- Seitenzahl: 312
- Erscheinungstermin: 29. Oktober 2004
- Englisch
- Abmessung: 235mm x 159mm x 24mm
- Gewicht: 570g
- ISBN-13: 9780471623915
- ISBN-10: 0471623911
- Artikelnr.: 13066440
Isao Noda, Proctor and Gamble Company, Ohio, USA. Yukihiro Ozaki, Kwansei Gakuin University, Japan.
Preface. Acknowledgements. 1 Introduction. 1.1 Two-dimensional
Spectroscopy. 1.2 Overview of the Field. 1.3 Generalized Two-dimensional
Correlation. 1.4 Heterospectral Correlation. 1.5 Universal Applicability. 2
Principle of Two-dimensional Correlation Spectroscopy. 2.1 Two-dimensional
Correlation Spectroscopy. 2.2 Generalized Two-dimensional Correlation. 2.3
Properties of 2D Correlation Spectra. 2.4 Analytical Expressions for
Certain 2D Spectra. 2.5 Cross-correlation Analysis and 2D Spectroscopy. 3
Practical Computation of Two-dimensional Correlation Spectra. 3.1
Computation of 2D Spectra from Discrete Data. 3.2 Unevenly Spaced Data. 3.3
Disrelation Spectrum. 3.4 Computational Efficiency. 4 Generalized
Two-dimensional Correlation Spectroscopy in Practice. 4.1 Practical
Example. 4.2 Pretreatment of Data. 4.3 Features Arising from Factors other
than Band Intensity Changes. 5 Further Expansion of Generalized
Two-dimensional Correlation Spectroscopy - Sample-Sample Correlation and
Hybrid Correlation. 5.1 Sample-Sample Correlation Spectroscopy. 5.2 Hybrid
2D Correlation Spectroscopy. 5.3 Additional Remarks. 6 Additional
Developments in Two-dimensional Correlation Spectroscopy - Statistical
Treatments, Global Phase Maps, and Chemometrics. 6.1 Classical Statistical
Treatments and 2D Spectroscopy. 6.2 Global 2D Phase Maps. 6.3 Chemometrics
and 2D Correlation Spectroscopy. 7 Other Types of Two-dimensional
Spectroscopy. 7.1 Nonlinear Optical 2D Spectroscopy. 7.2 Statistical 2D
Correlation Spectroscopy. 7.3 Other Developments in 2D Correlation
Spectroscopy. 8 Dynamic Two-dimensional Correlation Spectroscopy Based on
Periodic Perturbations. 8.1 Dynamic 2D IR Spectroscopy. 8.2 Dynamic 2D IR
Dichroism Spectra of Polymers. 8.3 Repetitive Perturbations Beyond DIRLD. 9
Applications of Two-dimensional Correlation Spectroscopy to Basic
Molecules. 9.1 2D IR Study of the Dissociation of Hydrogen-bonded
N-Methylacetamide. 9.2 2D NIR Sample-Sample Correlation Study of Phase
Transitions of Oleic Acid. 9.3 2D NIR Correlation Spectroscopy Study of
Water. 9.4 2D Fluorescence Study of Polynuclear Aromatic Hydrocarbons. 10
Generalized Two-dimensional Correlation Studies of Polymers and Liquid
Crystals. 10.1 Temperature and Pressure Effects on Polyethylene. 10.2
Reorientation of Nematic Liquid Crystals by an Electric Field. 10.3
Temperature-dependent 2D NIR of Amorphous Polyamide. 10.4 Composition-based
2D Raman Study of EVA Copolymers. 10.5 Polarization Angle-dependent 2D IR
Study of Ferroelectric Liquid Crystals. 11 Two-dimensional Correlation
Spectroscopy and Chemical Reactions. 11.1 2D ATR/IR Study of
Bis(hydroxyethyl terephthalate) Oligomerization. 11.2 Hydrogen-Deuterium
Exchange of Human Serum Albumin. 12 Protein Research by Two-dimensional
Correlation Spectroscopy. 12.1 Adsorption and Concentration-dependent 2D
ATR/IR Study of ²-Lactoglobulin. 12.2 pH-dependent 2D ATR/IR Study of Human
Serum Albumin. 12.3 Aggregation of Lipid-bound Cytochrome c. 13
Applications of Two-dimensional Correlation Spectroscopy to Biological and
Biomedical Sciences. 13.1 2D NIR Study of Milk. 13.2 2D IR Study of
Synthetic and Biological Apatites. 13.3 Identification and Quality Control
of Traditional Chinese Medicines. 14 Application of Heterospectral
Correlation Analysis. 14.1 Correlation between different Spectral
Measurements. 14.2 SAXS/IR Dichroism Correlation Study of Block Copolymer.
14.3 Raman/NIR Correlation Study of Partially Miscible Blends. 14.4
ATR/IR-NIR Correlation Study of BIS (hydroxyethyl terephthalate)
Oligomerization. 14.5 XAS/Raman Correlation Study of Electrochemical
Reaction of Lithium with CoO. 15 Extension of Two-dimensional Correlation
Analysis to Other Fields. 15.1 Applications of 2D Correlation beyond
Optical Spectroscopy. 15.2 2D Correlation Gel Permeation Chromatography
(GPC). 15.3 2D Mass Spectrometry. 15.4 Other Unusual Applications of 2D
Correlation Analysis. 15.5 Return to 2D NMR Spectroscopy. 15.6 Future
Developments. Index.
Spectroscopy. 1.2 Overview of the Field. 1.3 Generalized Two-dimensional
Correlation. 1.4 Heterospectral Correlation. 1.5 Universal Applicability. 2
Principle of Two-dimensional Correlation Spectroscopy. 2.1 Two-dimensional
Correlation Spectroscopy. 2.2 Generalized Two-dimensional Correlation. 2.3
Properties of 2D Correlation Spectra. 2.4 Analytical Expressions for
Certain 2D Spectra. 2.5 Cross-correlation Analysis and 2D Spectroscopy. 3
Practical Computation of Two-dimensional Correlation Spectra. 3.1
Computation of 2D Spectra from Discrete Data. 3.2 Unevenly Spaced Data. 3.3
Disrelation Spectrum. 3.4 Computational Efficiency. 4 Generalized
Two-dimensional Correlation Spectroscopy in Practice. 4.1 Practical
Example. 4.2 Pretreatment of Data. 4.3 Features Arising from Factors other
than Band Intensity Changes. 5 Further Expansion of Generalized
Two-dimensional Correlation Spectroscopy - Sample-Sample Correlation and
Hybrid Correlation. 5.1 Sample-Sample Correlation Spectroscopy. 5.2 Hybrid
2D Correlation Spectroscopy. 5.3 Additional Remarks. 6 Additional
Developments in Two-dimensional Correlation Spectroscopy - Statistical
Treatments, Global Phase Maps, and Chemometrics. 6.1 Classical Statistical
Treatments and 2D Spectroscopy. 6.2 Global 2D Phase Maps. 6.3 Chemometrics
and 2D Correlation Spectroscopy. 7 Other Types of Two-dimensional
Spectroscopy. 7.1 Nonlinear Optical 2D Spectroscopy. 7.2 Statistical 2D
Correlation Spectroscopy. 7.3 Other Developments in 2D Correlation
Spectroscopy. 8 Dynamic Two-dimensional Correlation Spectroscopy Based on
Periodic Perturbations. 8.1 Dynamic 2D IR Spectroscopy. 8.2 Dynamic 2D IR
Dichroism Spectra of Polymers. 8.3 Repetitive Perturbations Beyond DIRLD. 9
Applications of Two-dimensional Correlation Spectroscopy to Basic
Molecules. 9.1 2D IR Study of the Dissociation of Hydrogen-bonded
N-Methylacetamide. 9.2 2D NIR Sample-Sample Correlation Study of Phase
Transitions of Oleic Acid. 9.3 2D NIR Correlation Spectroscopy Study of
Water. 9.4 2D Fluorescence Study of Polynuclear Aromatic Hydrocarbons. 10
Generalized Two-dimensional Correlation Studies of Polymers and Liquid
Crystals. 10.1 Temperature and Pressure Effects on Polyethylene. 10.2
Reorientation of Nematic Liquid Crystals by an Electric Field. 10.3
Temperature-dependent 2D NIR of Amorphous Polyamide. 10.4 Composition-based
2D Raman Study of EVA Copolymers. 10.5 Polarization Angle-dependent 2D IR
Study of Ferroelectric Liquid Crystals. 11 Two-dimensional Correlation
Spectroscopy and Chemical Reactions. 11.1 2D ATR/IR Study of
Bis(hydroxyethyl terephthalate) Oligomerization. 11.2 Hydrogen-Deuterium
Exchange of Human Serum Albumin. 12 Protein Research by Two-dimensional
Correlation Spectroscopy. 12.1 Adsorption and Concentration-dependent 2D
ATR/IR Study of ²-Lactoglobulin. 12.2 pH-dependent 2D ATR/IR Study of Human
Serum Albumin. 12.3 Aggregation of Lipid-bound Cytochrome c. 13
Applications of Two-dimensional Correlation Spectroscopy to Biological and
Biomedical Sciences. 13.1 2D NIR Study of Milk. 13.2 2D IR Study of
Synthetic and Biological Apatites. 13.3 Identification and Quality Control
of Traditional Chinese Medicines. 14 Application of Heterospectral
Correlation Analysis. 14.1 Correlation between different Spectral
Measurements. 14.2 SAXS/IR Dichroism Correlation Study of Block Copolymer.
14.3 Raman/NIR Correlation Study of Partially Miscible Blends. 14.4
ATR/IR-NIR Correlation Study of BIS (hydroxyethyl terephthalate)
Oligomerization. 14.5 XAS/Raman Correlation Study of Electrochemical
Reaction of Lithium with CoO. 15 Extension of Two-dimensional Correlation
Analysis to Other Fields. 15.1 Applications of 2D Correlation beyond
Optical Spectroscopy. 15.2 2D Correlation Gel Permeation Chromatography
(GPC). 15.3 2D Mass Spectrometry. 15.4 Other Unusual Applications of 2D
Correlation Analysis. 15.5 Return to 2D NMR Spectroscopy. 15.6 Future
Developments. Index.
Preface. Acknowledgements. 1 Introduction. 1.1 Two-dimensional
Spectroscopy. 1.2 Overview of the Field. 1.3 Generalized Two-dimensional
Correlation. 1.4 Heterospectral Correlation. 1.5 Universal Applicability. 2
Principle of Two-dimensional Correlation Spectroscopy. 2.1 Two-dimensional
Correlation Spectroscopy. 2.2 Generalized Two-dimensional Correlation. 2.3
Properties of 2D Correlation Spectra. 2.4 Analytical Expressions for
Certain 2D Spectra. 2.5 Cross-correlation Analysis and 2D Spectroscopy. 3
Practical Computation of Two-dimensional Correlation Spectra. 3.1
Computation of 2D Spectra from Discrete Data. 3.2 Unevenly Spaced Data. 3.3
Disrelation Spectrum. 3.4 Computational Efficiency. 4 Generalized
Two-dimensional Correlation Spectroscopy in Practice. 4.1 Practical
Example. 4.2 Pretreatment of Data. 4.3 Features Arising from Factors other
than Band Intensity Changes. 5 Further Expansion of Generalized
Two-dimensional Correlation Spectroscopy - Sample-Sample Correlation and
Hybrid Correlation. 5.1 Sample-Sample Correlation Spectroscopy. 5.2 Hybrid
2D Correlation Spectroscopy. 5.3 Additional Remarks. 6 Additional
Developments in Two-dimensional Correlation Spectroscopy - Statistical
Treatments, Global Phase Maps, and Chemometrics. 6.1 Classical Statistical
Treatments and 2D Spectroscopy. 6.2 Global 2D Phase Maps. 6.3 Chemometrics
and 2D Correlation Spectroscopy. 7 Other Types of Two-dimensional
Spectroscopy. 7.1 Nonlinear Optical 2D Spectroscopy. 7.2 Statistical 2D
Correlation Spectroscopy. 7.3 Other Developments in 2D Correlation
Spectroscopy. 8 Dynamic Two-dimensional Correlation Spectroscopy Based on
Periodic Perturbations. 8.1 Dynamic 2D IR Spectroscopy. 8.2 Dynamic 2D IR
Dichroism Spectra of Polymers. 8.3 Repetitive Perturbations Beyond DIRLD. 9
Applications of Two-dimensional Correlation Spectroscopy to Basic
Molecules. 9.1 2D IR Study of the Dissociation of Hydrogen-bonded
N-Methylacetamide. 9.2 2D NIR Sample-Sample Correlation Study of Phase
Transitions of Oleic Acid. 9.3 2D NIR Correlation Spectroscopy Study of
Water. 9.4 2D Fluorescence Study of Polynuclear Aromatic Hydrocarbons. 10
Generalized Two-dimensional Correlation Studies of Polymers and Liquid
Crystals. 10.1 Temperature and Pressure Effects on Polyethylene. 10.2
Reorientation of Nematic Liquid Crystals by an Electric Field. 10.3
Temperature-dependent 2D NIR of Amorphous Polyamide. 10.4 Composition-based
2D Raman Study of EVA Copolymers. 10.5 Polarization Angle-dependent 2D IR
Study of Ferroelectric Liquid Crystals. 11 Two-dimensional Correlation
Spectroscopy and Chemical Reactions. 11.1 2D ATR/IR Study of
Bis(hydroxyethyl terephthalate) Oligomerization. 11.2 Hydrogen-Deuterium
Exchange of Human Serum Albumin. 12 Protein Research by Two-dimensional
Correlation Spectroscopy. 12.1 Adsorption and Concentration-dependent 2D
ATR/IR Study of ²-Lactoglobulin. 12.2 pH-dependent 2D ATR/IR Study of Human
Serum Albumin. 12.3 Aggregation of Lipid-bound Cytochrome c. 13
Applications of Two-dimensional Correlation Spectroscopy to Biological and
Biomedical Sciences. 13.1 2D NIR Study of Milk. 13.2 2D IR Study of
Synthetic and Biological Apatites. 13.3 Identification and Quality Control
of Traditional Chinese Medicines. 14 Application of Heterospectral
Correlation Analysis. 14.1 Correlation between different Spectral
Measurements. 14.2 SAXS/IR Dichroism Correlation Study of Block Copolymer.
14.3 Raman/NIR Correlation Study of Partially Miscible Blends. 14.4
ATR/IR-NIR Correlation Study of BIS (hydroxyethyl terephthalate)
Oligomerization. 14.5 XAS/Raman Correlation Study of Electrochemical
Reaction of Lithium with CoO. 15 Extension of Two-dimensional Correlation
Analysis to Other Fields. 15.1 Applications of 2D Correlation beyond
Optical Spectroscopy. 15.2 2D Correlation Gel Permeation Chromatography
(GPC). 15.3 2D Mass Spectrometry. 15.4 Other Unusual Applications of 2D
Correlation Analysis. 15.5 Return to 2D NMR Spectroscopy. 15.6 Future
Developments. Index.
Spectroscopy. 1.2 Overview of the Field. 1.3 Generalized Two-dimensional
Correlation. 1.4 Heterospectral Correlation. 1.5 Universal Applicability. 2
Principle of Two-dimensional Correlation Spectroscopy. 2.1 Two-dimensional
Correlation Spectroscopy. 2.2 Generalized Two-dimensional Correlation. 2.3
Properties of 2D Correlation Spectra. 2.4 Analytical Expressions for
Certain 2D Spectra. 2.5 Cross-correlation Analysis and 2D Spectroscopy. 3
Practical Computation of Two-dimensional Correlation Spectra. 3.1
Computation of 2D Spectra from Discrete Data. 3.2 Unevenly Spaced Data. 3.3
Disrelation Spectrum. 3.4 Computational Efficiency. 4 Generalized
Two-dimensional Correlation Spectroscopy in Practice. 4.1 Practical
Example. 4.2 Pretreatment of Data. 4.3 Features Arising from Factors other
than Band Intensity Changes. 5 Further Expansion of Generalized
Two-dimensional Correlation Spectroscopy - Sample-Sample Correlation and
Hybrid Correlation. 5.1 Sample-Sample Correlation Spectroscopy. 5.2 Hybrid
2D Correlation Spectroscopy. 5.3 Additional Remarks. 6 Additional
Developments in Two-dimensional Correlation Spectroscopy - Statistical
Treatments, Global Phase Maps, and Chemometrics. 6.1 Classical Statistical
Treatments and 2D Spectroscopy. 6.2 Global 2D Phase Maps. 6.3 Chemometrics
and 2D Correlation Spectroscopy. 7 Other Types of Two-dimensional
Spectroscopy. 7.1 Nonlinear Optical 2D Spectroscopy. 7.2 Statistical 2D
Correlation Spectroscopy. 7.3 Other Developments in 2D Correlation
Spectroscopy. 8 Dynamic Two-dimensional Correlation Spectroscopy Based on
Periodic Perturbations. 8.1 Dynamic 2D IR Spectroscopy. 8.2 Dynamic 2D IR
Dichroism Spectra of Polymers. 8.3 Repetitive Perturbations Beyond DIRLD. 9
Applications of Two-dimensional Correlation Spectroscopy to Basic
Molecules. 9.1 2D IR Study of the Dissociation of Hydrogen-bonded
N-Methylacetamide. 9.2 2D NIR Sample-Sample Correlation Study of Phase
Transitions of Oleic Acid. 9.3 2D NIR Correlation Spectroscopy Study of
Water. 9.4 2D Fluorescence Study of Polynuclear Aromatic Hydrocarbons. 10
Generalized Two-dimensional Correlation Studies of Polymers and Liquid
Crystals. 10.1 Temperature and Pressure Effects on Polyethylene. 10.2
Reorientation of Nematic Liquid Crystals by an Electric Field. 10.3
Temperature-dependent 2D NIR of Amorphous Polyamide. 10.4 Composition-based
2D Raman Study of EVA Copolymers. 10.5 Polarization Angle-dependent 2D IR
Study of Ferroelectric Liquid Crystals. 11 Two-dimensional Correlation
Spectroscopy and Chemical Reactions. 11.1 2D ATR/IR Study of
Bis(hydroxyethyl terephthalate) Oligomerization. 11.2 Hydrogen-Deuterium
Exchange of Human Serum Albumin. 12 Protein Research by Two-dimensional
Correlation Spectroscopy. 12.1 Adsorption and Concentration-dependent 2D
ATR/IR Study of ²-Lactoglobulin. 12.2 pH-dependent 2D ATR/IR Study of Human
Serum Albumin. 12.3 Aggregation of Lipid-bound Cytochrome c. 13
Applications of Two-dimensional Correlation Spectroscopy to Biological and
Biomedical Sciences. 13.1 2D NIR Study of Milk. 13.2 2D IR Study of
Synthetic and Biological Apatites. 13.3 Identification and Quality Control
of Traditional Chinese Medicines. 14 Application of Heterospectral
Correlation Analysis. 14.1 Correlation between different Spectral
Measurements. 14.2 SAXS/IR Dichroism Correlation Study of Block Copolymer.
14.3 Raman/NIR Correlation Study of Partially Miscible Blends. 14.4
ATR/IR-NIR Correlation Study of BIS (hydroxyethyl terephthalate)
Oligomerization. 14.5 XAS/Raman Correlation Study of Electrochemical
Reaction of Lithium with CoO. 15 Extension of Two-dimensional Correlation
Analysis to Other Fields. 15.1 Applications of 2D Correlation beyond
Optical Spectroscopy. 15.2 2D Correlation Gel Permeation Chromatography
(GPC). 15.3 2D Mass Spectrometry. 15.4 Other Unusual Applications of 2D
Correlation Analysis. 15.5 Return to 2D NMR Spectroscopy. 15.6 Future
Developments. Index.