Chichester, West Sussex, England ; ; Hoboken, NJ, : John Wiley & Sons, c2004

1-280-27465-4

9786610274659

0-470-01240-4

0-470-01239-0

1 online resource (295 pages) : illustrations (black and white)

OzakiY (Yukihiro)

539/.6

Vibrational spectra

Linear free energy relationship

Spectrum analysis

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

Two-dimensional Correlation Spectroscopy - Applications in Vibrational and Optical Spectroscopy; Contents; Preface; Acknowledgements; 1 Introduction; 1.1 Two-dimensional Spectroscopy; 1.2 Overview of the Field; 1.3 Generalized Two-dimensional Correlation; 1.3.1 Types of Spectroscopic Probes; 1.3.2 External Perturbations; 1.4 Heterospectral Correlation; 1.5 Universal Applicability; 2 Principle of Two-dimensional Correlation Spectroscopy; 2.1 Two-dimensional Correlation Spectroscopy; 2.1.1 General Scheme; 2.1.2 Type of External Perturbations; 2.2 Generalized Two-dimensional Correlation

2.2.1 Dynamic Spectrum2.2.2 Two-dimensional Correlation Concept; 2.2.3 Generalized Two-dimensional Correlation Function; 2.2.4 Heterospectral Correlation; 2.3 Properties of 2D Correlation Spectra; 2.3.1 Synchronous 2D Correlation Spectrum; 2.3.2 Asynchronous 2D Correlation Spectrum; 2.3.3 Special Cases and Exceptions; 2.4 Analytical Expressions for Certain 2D Spectra; 2.4.1 Comparison of Linear Functions; 2.4.2 2D Spectra Based on Sinusoidal Signals; 2.4.3

Exponentially Decaying Intensities; 2.4.4 Distributed Lorentzian Peaks; 2.4.5 Signals with more Complex Waveforms

2.5 Cross-correlation Analysis and 2D Spectroscopy2.5.1 Cross-correlation Function and Cross Spectrum; 2.5.2 Cross-correlation Function and Synchronous Spectrum; 2.5.3 Hilbert Transform; 2.5.4 Orthogonal Correlation Function and Asynchronous Spectrum; 2.5.5 Disrelation Spectrum; 3 Practical Computation of Two-dimensional Correlation Spectra; 3.1 Computation of 2D Spectra from Discrete Data; 3.1.1 Synchronous Spectrum; 3.1.2 Asynchronous Spectrum; 3.2 Unevenly Spaced Data; 3.3 Disrelation Spectrum; 3.4 Computational Efficiency; 4 Generalized Two-dimensional Correlation Spectroscopy in Practice

4.1 Practical Example4.1.1 Solvent Evaporation Study; 4.1.2 2D Spectra Generated from Experimental Data; 4.1.3 Sequential Order Analysis by Cross Peak Signs; 4.2 Pretreatment of Data; 4.2.1 Noise Reduction Methods; 4.2.2 Baseline Correction Methods; 4.2.3 Other Pretreatment Methods; 4.3 Features Arising from Factors other than Band Intensity Changes; 4.3.1 Effect of Band Position Shift and Line Shape Change; 4.3.2 Simulation Studies; 4.3.3 2D Spectral Features from Band Shift and Line Broadening

5 Further Expansion of Generalized Two-dimensional Correlation Spectroscopy - Sample-Sample Correlation and Hybrid Correlation5.1 Sample-Sample Correlation Spectroscopy; 5.1.1 Correlation in another Dimension; 5.1.2 Matrix Algebra Outlook of 2D Correlation; 5.1.3 Sample-Sample Correlation Spectra; 5.1.4 Application of Sample-Sample Correlation; 5.2 Hybrid 2D Correlation Spectroscopy; 5.2.1 Multiple Perturbations; 5.2.2 Correlation between Data Matrices; 5.2.3 Case Studies; 5.3 Additional Remarks

6 Additional Developments in Two-dimensional Correlation Spectroscopy - Statistical Treatments, Global Phase Maps, and Chemometrics

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 reveiwsGrowing number of applications of this methodology - book now needed for people thinking of using this techniqueLimitations and benefits discussed and comparisons made with 2D NMRDiscusses 20 optical and vibrational s