一本关于NMR弛豫的专著 Practical NMR relaxation for chemists

　　论坛上不少朋友对NMR驰豫的问题感兴趣，现上载一本关于NMR弛豫的专著供有兴趣者研读。

　　该书虽然是为化学家所写，但还是需要有一些物理学和NMR背景知识。该书对在实验室工作的NMR工作者是有用的。

　　这本书可能是教授化学家NMR驰豫技术的第一本专著。2005年出版，还是比较新的。

　　Practical NMR relaxation for chemists

　　Author: Bakhmutov, Vladimir , I.

　　Publisher: John Wiley & Sons, Ltd.

　　Format: Adobe (Encrypted PDF)

　　Content Language: English

　　Contents

　　1 How and Why Nuclei Relax 1

　　1.1 Nucleus in an External Magnetic Field 4

　　1.2 Spin–Lattice and Spin–Spin Nuclear Relaxation 7

　　1.2.1 Macroscopic Magnetization: Relaxation

　　Times T1 and T2 8

　　1.3 Molecular Motions as the Reason

　　for Nuclear Relaxation 11

　　1.3.1 Correlation Times and Activation Energies

　　of Molecular Motions 13

　　1.3.2 Isotropic and Anisotropic Molecular Motions 15

　　Bibliography 18

　　2 How to Measure NMR Relaxation

　　Times 19

　　2.1 Exponential and Non-exponential

　　Nuclear Relaxation 20

　　2.2 Measurements of Spin–Lattice

　　Relaxation Times 20

　　2.3 Measurements of Selective and Biselective

　　T1 Times 24

　　2.4 Determination of T1ρ and T2 27

　　2.5 Preparation of Samples for Relaxation

　　Experiments 28

　　Bibliography 29

　　3 Errors in Determinations

　　of Relaxation Times 31

　　3.1 Instrumental Errors 32

　　3.2 Incorrect Parameters for T1, T2 Measurements

　　and T1, T2 Calculations 33

　　3.3 Coupled Nuclear Relaxation 34

　　3.4 Chemical Exchange 37

　　Bibliography 42

　　4 NMR Relaxation by Dipole–Dipole

　　and Quadrupole Interactions 43

　　4.1 Intramolecular Dipole–Dipole Relaxation:

　　Homo- and Heteronuclear Dipolar Coupling and

　　the Spectral Density Function 44

　　4.2 How to Reveal the Presence of the Dipolar

　　Mechanism 48

　　4.2.1 NOE as a Test for Dipole–Dipole Nuclear

　　Relaxation 48

　　4.2.2 Evaluations of the Dipolar Contributions from

　　Selective and Nonselective T1 Times 52

　　Contents ...

　　Contents vii

　　4.3 Intermolecular Dipole–Dipole Interactions 53

　　4.4 Electric Field Gradients

　　at Quadrupolar Nuclei 53

　　4.5 Nuclear Quadrupole Coupling Constant

　　as Measure of the Electric Field Gradient 54

　　4.6 Quadrupole Relaxation 56

　　Bibliography 57

　　5 Relaxation by Chemical Shift

　　Anisotropy, Spin–Rotation

　　Relaxation, Scalar Relaxation

　　of the Second Kind

　　and Cross-mechanisms 59

　　5.1 Relaxation by Chemical Shift Anisotropy 59

　　5.2 Spin–Rotation Relaxation 63

　　5.3 Interference Mechanisms of Nuclear Relaxation 64

　　5.4 Scalar Relaxation of the Second Kind 65

　　Bibliography 67

　　6 Nuclear Relaxation in Molecular

　　Systems with Anisotropic Motions 69

　　6.1 Spin–Lattice Nuclear Relaxation in Ellipsoidal

　　Molecules: Temperature Dependences

　　of T1 Times 70

　　6.2 How to Reveal Anisotropic Molecular Motions

　　in Solution 74

　　viii Contents

　　6.3 Nuclear Relaxation in the Presence

　　of Correlation Time Distributions 76

　　Bibliography 80

　　7 1H T1 Relaxation Diagnostics

　　in Solution 81

　　7.1 Revealing Weak Intermolecular Interactions

　　by T1 Time Measurements in Solution 82

　　7.2 T1 Studies of Exchange in Simple Molecular

　　Systems 87

　　7.3 Structural 1H T1 Criterion 89

　　7.4 Partially Relaxed NMR Spectra 92

　　Bibliography 94

　　8 Internuclear Distances from 1H T1

　　Relaxation Measurements

　　in Solution 97

　　8.1 X−H Distances: Metal–Hydride

　　Bond Lengths 98

　　8.1.1 How to Determine Metal–Hydride Bond Lengths

　　by Standard 1H T1 Measurements 101

　　8.1.2 Metal–Hydride Bond Lengths by 1H T1sel

　　and 1H T1min Measurements 104

　　8.2 Proton–Proton Distances by Standard

　　1H T1 Measurements 108

　　8.3 H−H Distances by T1sel/T1bis Measurements 111

　　8.4 H...H Distances in Intermediates 115

　　11 Relaxation of Nuclei Other Than 1H

　　and 2H and Specific Relaxation

　　Experiments 155

　　11.1 Chemical Shift Anisotropies and Nuclear

　　Quadrupole Coupling Constants from T1 Times

　　of Heavy Nuclei in Solution 156

　　11.2 Multinuclear Relaxation Approaches to

　　Complexation, Association and H-bonding 159

　　11.3 23Na Relaxation in Solutions of Complex

　　Molecular Systems 162

　　11.4 Character of Molecular Motions from 17O and 2H

　　T1 Relaxation in Solution 165

　　11.5 Two-dimensional T1 and T1ρ NMR Experiments 166

　　11.6 Chemical Exchange in Complex Molecular

　　Systems from 15N Relaxation in Solution 168

　　11.7 R1/R2 Method 170

　　11.8 Cross-correlation Relaxation Rates

　　and Structures of Complex Molecular

　　Systems in Solution 172

　　11.9 Variable-field Relaxation Experiments 174

　　Bibliography 176

　　12 Paramagnetic NMR Relaxation 179

　　12.1 Theoretical Basis of Paramagnetic Relaxation

　　Enhancement 179

　　12.2 Paramagnetic Relaxation Rate Enhancements

　　in the Presence of Chemical Exchange 185

　　12.3 Structural Applications of Paramagnetic

　　Relaxation Rate Enhancement 187

　　12.4 Kinetics of Ligand Exchange via Paramagnetic

　　Relaxation Rate Enhancement 191

　　12.5 Longitudinal Electron Relaxation Time

　　at Paramagnetic Centers from

　　Variable-high-field NMR Experiments 193

　　Bibliography 195

　　化学家实用NMR驰豫

　　Practical NMR relaxation for chemists