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TABLE OF CONTENTS
Foreword.
Preface.

1 Introduction to Nuclear Magnetic Resonance.

1.1 Basic Principle of NMR.

1.2 Chemical Shift.

1.3 Spin?spin Coupling.

1.4 Magnetization.

1.5 Relaxation Process.

1.6 Pulse-Fourier Transform NMR Spectrometer.

1.7 Recent Developments in NMR Spectroscopy.

1.8 References.

2 1H NMR Spectroscopy.

2.1 Chemical Shift.

2.2 Coupling Constant J.

2.3 Spin?spin Coupling System and Classification of NMR Spectra.

2.4 Common Second-order Spectra.

2.5 Spectra of Common Functional Groups.

2.6 Methods for Assisting the Spectrum Analysis.

2.7 Double Resonance.

2.8 Dynamic Nuclear Magnetic Resonance.

2.9 Interpreting 1H NMR Spectra.

2.10 References.

3 13C NMR Spectroscopy.

3.1 Introduction.

3.2 Chemical Shift.

3.3 Coupling and Decoupling Methods in 13C Spectra.

3.4 Relaxation.

3.5 Interpretation of 13C NMR Spectra.

3.6 References.

4 Application of Pulse Sequences and Two-dimensional NMR Spectroscopy.

4.1 Fundamentals.

4.2 Spectrum Editing.

4.3 Introduction to 2D NMR.

4.4 J Resolved Spectra.

4.5 Heteronuclear Shift Correlation Spectroscopy.

4.6 Homonuclear Shift Correlation Spectroscopy.

4.7 NOESY and its Variations.

4.8 Relayed Correlation Spectra and Total Correlation Spectra.

4.9 Multiple Quantum 2D NMR Spectra.

4.10 1H Detected Heteronuclear Correlation Spectra.

4.11 Combined 2D NMR Spectra.

4.12 Three-dimensional NMR Spectra.

4.13 DOSY.

4.14 References.

5 Organic Mass Spectrometry.

5.1 Fundamentals of Organic Mass Spectrometry.

5.2 Mass Analyzers.

5.3 Ionization.

5.4Metastable Ions and their Measurement.

5.5 Tandem Mass Spectrometry (MSn).

5.6 Combination of Chromatography and Mass Spectrometry.

5.7 References.

6 Interpretation of Mass Spectra.

6.1 Determination of Molecular Weight and Elemental Composition.

6.2 Reactions and their Mechanisms in Organic Mass Spectrometry.

6.3 Mass Spectrum Patterns of Common Functional Groups.

6.4 Interpretation of Mass Spectra.

6.5 Library Retrieval of Mass Spectra.

6.6 Interpretation of the Mass Spectra from Soft Ionization.

6.7 References.

7 Infrared Spectroscopy and Raman Spectroscopy.

7.1 General Information on Infrared Spectroscopy.

7.2 Basic Theory of IR Spectroscopy.

7.3 Characteristic Frequencies of Functional Groups.

7.4 Interpretation of IR Spectra.

7.5 Recent Developments in Infrared Spectroscopy.

7.6 Principle and Application of Raman Spectroscopy.

7.7 References.

8 Identification of an Unknown Compound through a Combination of Spectra.

8.1 Structural Identification of an Unknown Compound by Combination of One-dimensional NMR and Other Spectra.

8.2 Determination of the Functional Groups (or Structural Units) of an Unknown Compound.

8.3 Deduction of the Structure of an Organic Compound on the Basis of 2D NMR Spectra.

8.4 Examples of Structural Identification or Assignment.

8.5 References.

9 Determination of Configuration and Conformation of Organic Compounds by Spectroscopic Methods.

9.1 NMR.

9.2 Mass Spectrometry.

9.3 Infrared and Raman Spectroscopy.

9.4 References.

Appendix 1: Product Operator Formalism for Pulse Sequences.

Appendix 2: Characteristic Frequencies of Common Functional Groups.

Index.

Clearly structured, easy to read and optimal to understand, this extensive compendium fills the gap between textbooks devoted to either spectra interpretation or basic physical principles. The original Chinese editions have already sold over 18,500 copies, and the material is taken from the latest literature from around the world, plus technical information provided by the manufacturers of spectroscopic instruments.
Alongside basic methods, Professor Ning presents up-to-date developments in NMR, MS, IR and Raman spectroscopy, such as pulsed-field gradient technique, LC-NMR, and DOSY. He stresses the application of spectroscopic methods, interpreting them in great detail and depth since most of the selected spectra may be applied to practical work, as well as summarizing the rules for their interpretation. He also incorporates his original ideas, including a comparison of the common points in different spectroscopic techniques.

This monograph features a unique structure, a typical example being the discussion of 2D NMR starting from pulse sequence units, which construct various pulse sequences for related 2D NMR. A complete chapter deals with the determination of configurations and conformations of organic compounds and even biological molecules from the viewpoint of spectroscopic methodologies, while one whole section is dedicated to the interpretation of mass spectra produced by soft ionization techniques.

The principles of mass analyzers, especially the ion trap, are discussed in great depth, together with a concise summary of the MS fragmentation and rearrangement of common compounds, allowing readers to easily predict related mass spectrometric reactions. All the threekinds of library retrieval of mass spectra are presented in detail, together with recent developments in molecular vibration spectroscopy. The whole is rounded off with several appendices, including a subject index for rapid reference.


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