| Preface to the Third Edition |
| Introduction / 1: |
| Origins and Early History of NMR / 1.1: |
| High Resolution NMR: An Overview / 1.2: |
| Additional Reading and Resources / 1.3: |
| The Theory of NMR / 2: |
| Nuclear Spin and Magnetic Moment / 2.1: |
| Theoretical Descriptions of NMR / 2.2: |
| Steady-State Quantum Mechanical Description / 2.3: |
| Effect of the Boltzmann Distribution / 2.4: |
| Spin-Lattice Relaxation / 2.5: |
| Precession of Nuclear Magnetic Moments / 2.6: |
| Classical Mechanical Description of NMR / 2.7: |
| Magnetization in the Rotating Frame / 2.8: |
| Methods of Obtaining NMR Spectra / 2.9: |
| Dynamic Processes / 2.10: |
| Terminology, Symbols, Units, and Conventions / 2.11: |
| Problems / 2.12: |
| Instrumentation and Techniques / 3: |
| Advantages of Pulse Fourier Transform NMR / 3.1: |
| Basic NMR Apparatus / 3.2: |
| Requirements for High Resolution NMR / 3.3: |
| Detection of NMR Signals / 3.4: |
| Phase Cycling / 3.5: |
| Fourier Transformation of the FID / 3.6: |
| Data Acquisition / 3.7: |
| Data Processing / 3.8: |
| Digital Filtering / 3.9: |
| Alternatives to Fourier Transformation / 3.10: |
| Sensitivity and Size of Sample / 3.11: |
| Useful Solvents / 3.12: |
| Chemical Shifts / 3.13: |
| The Origin of Chemical Shifts / 4.1: |
| Theory of Chemical Shifts / 4.2: |
| Measurement of Chemical Shifts / 4.3: |
| Empirical Correlations of Chemical Shifts / 4.4: |
| Some Aspects of Proton Chemical Shifts / 4.5: |
| Nuclei Other Than Hydrogen / 4.6: |
| Compilations of Spectral Data and Empirical Estimates of Chemical Shifts / 4.7: |
| Isotope Effects / 4.8: |
| Effects of Molecular Asymmetry / 4.9: |
| Paramagnetic Species / 4.10: |
| Coupling between Pairs of Spins / 4.11: |
| Origin of Spin Coupling Interactions / 5.1: |
| General Aspects of Spin-Spin Coupling / 5.2: |
| Theory of Spin-Spin Coupling / 5.3: |
| Correlation of Coupling Constants with Other Physical Properties / 5.4: |
| Effect of Exchange / 5.5: |
| Spin Decoupling and Double Resonance / 5.6: |
| Structure and Analysis of Complex Spectra / 5.7: |
| Symmetry and Equivalence / 6.1: |
| Notation / 6.2: |
| Energy Levels and Transitions in an AX System / 6.3: |
| Quantum Mechanical Treatment / 6.4: |
| The Two-Spin System without Coupling / 6.5: |
| Factoring the Secular Equation / 6.6: |
| Two Coupled Spins / 6.7: |
| The AB Spectrum / 6.8: |
| AX, AB, and A[subscript 2] Spectra / 6.9: |
| "First-Order" Spectra / 6.10: |
| Symmetry of Spin Wave Functions / 6.11: |
| General Procedures for Simulating Spectra / 6.12: |
| Three-Spin Systems / 6.13: |
| Relative Signs of Coupling Constants / 6.14: |
| Some Consequences of Strong Coupling and Chemical Equivalence / 6.15: |
| "Satellites" from Carbon-13 and Other Nuclides / 6.16: |
| The AA'BB' and AA'XX' Systems / 6.17: |
| Spectra of Solids / 6.18: |
| Spin Interactions in Solids / 7.1: |
| Dipolar Interactions / 7.2: |
| "Scalar Coupling" / 7.3: |
| The Heteronuclear Two-Spin System / 7.4: |
| Dipolar Decoupling / 7.5: |
| Cross Polarization / 7.6: |
| The Homonuclear Two-Spin System / 7.7: |
| Line Narrowing by Multiple Pulse Methods / 7.8: |
| Anisotropy of the Chemical Shielding / 7.9: |
| Magic Angle Spinning / 7.10: |
| Quadrupole Interactions and Line-Narrowing Methods / 7.11: |
| Other Aspects of Line Shapes / 7.12: |
| Orientation Effects in Liquids: Liquid Crystals / 7.13: |
| Relaxation / 7.14: |
| Molecular Motions and Processes for Relaxation in Liquids / 8.1: |
| Nuclear Magnetic Dipole Interactions / 8.2: |
| Nuclear Overhauser Effect / 8.3: |
| Relaxation via Chemical Shielding Anisotropy / 8.4: |
| Electric Quadrupole Relaxation / 8.5: |
| Scalar Relaxation / 8.6: |
| Spin-Rotation Relaxation / 8.7: |
| Relaxation by Paramagnetic Substances / 8.8: |
| Other Factors Affecting Relaxation / 8.9: |
| Pulse Sequences / 8.10: |
| The Spin Echo / 9.1: |
| The Carr-Purcell Pulse Sequence / 9.2: |
| Correcting for Pulse Imperfections / 9.3: |
| Spin Locking / 9.4: |
| Selective Excitation / 9.5: |
| Decoupling / 9.6: |
| Polarization Transfer Methods / 9.7: |
| Two-Dimensional NMR / 9.8: |
| General Aspects of 2D Spectra / 10.1: |
| A Survey of Basic 2D Experiments / 10.2: |
| Data Acquisition and Processing / 10.3: |
| Sensitivity Considerations / 10.4: |
| Density Matrix and Product Operator Formalisms / 10.5: |
| The Density Matrix / 11.1: |
| Transformations of the Density Matrix / 11.2: |
| The One-Spin System / 11.3: |
| The Two-Spin System / 11.4: |
| INEPT and Related Pulse Sequences / 11.5: |
| Product Operators / 11.6: |
| Coherence Transfer Pathways / 11.7: |
| Selected 1D, 2D, and 3D Experiments: A Further Look / 11.8: |
| Spectral Editing / 12.1: |
| Double Quantum Filtering Experiments / 12.2: |
| COSY / 12.3: |
| Heteronuclear Correlation by Indirect Detection / 12.4: |
| Three- and Four-Dimensional NMR / 12.5: |
| Elucidation of Molecular Structure and Macromolecular Conformation / 12.6: |
| Organic Structure Elucidation / 13.1: |
| Application of Some Useful 2D Methods / 13.2: |
| Structure and Configuration of Polymers / 13.3: |
| Three-Dimensional Structure of Biopolymers / 13.4: |
| NMR Imaging and Spatially Localized Spectroscopy / 13.5: |
| Use of Magnetic Field Gradients to Produce Images / 14.1: |
| Use of 2D NMR Methods in Imaging / 14.2: |
| k Space; Echo Planar Imaging / 14.3: |
| Factors Affecting Image Contrast / 14.4: |
| Chemical Shift Imaging and in Vivo Spectroscopy / 14.5: |
| NMR Imaging in Solids / 14.6: |
| Properties of Common Nuclear Spins / 14.7: |
| ABX and AA'XX' Spectra / Appendix B: |
| The ABX System / B.1: |
| The AA'XX' System / B.2: |
| Review of Relevant Mathematics / Appendix C: |
| Complex Numbers / C.1: |
| Trigonometric Identities / C.2: |
| Vectors / C.3: |
| Matrices / C.4: |
| Spin Matrices / Appendix D: |
| One Spin / D.1: |
| Two-Spin System / D.2: |
| Selected Answers to Problems / Appendix E: |
| References |
| Index |
| Preface to the Third Edition |
| Introduction / 1: |
| Origins and Early History of NMR / 1.1: |
| High Resolution NMR: An Overview / 1.2: |
| Additional Reading and Resources / 1.3: |
| The Theory of NMR / 2: |
