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Physics
Nuclear and Particle Physics
Nuclear Magnetic Resonance (NMR)
1. Fundamental Principles of Nuclear Magnetism
2. NMR Instrumentation and Hardware
3. Basic NMR Experiments and Data Acquisition
4. Chemical Shift and Spectral Interpretation
5. Spin-Spin Coupling and Multiplicity
6. Integration and Quantitative Analysis
7. Advanced One-Dimensional Techniques
8. Two-Dimensional NMR Spectroscopy
9. Multinuclear NMR
10. Specialized NMR Techniques
11. NMR Applications and Problem Solving
12. Magnetic Resonance Imaging (MRI)
7.
Advanced One-Dimensional Techniques
7.1.
Decoupling Experiments
7.1.1.
Homonuclear Decoupling
7.1.1.1.
Selective Irradiation
7.1.1.2.
Broadband Decoupling
7.1.1.3.
Difference Spectroscopy
7.1.2.
Heteronuclear Decoupling
7.1.2.1.
Proton Decoupling
7.1.2.2.
Composite Pulse Decoupling
7.1.2.3.
Gated Decoupling
7.1.3.
Applications and Interpretation
7.1.3.1.
Spectral Simplification
7.1.3.2.
Assignment Confirmation
7.1.3.3.
Coupling Network Elucidation
7.2.
Nuclear Overhauser Effect (NOE)
7.2.1.
Physical Basis
7.2.1.1.
Dipole-Dipole Relaxation
7.2.1.2.
Cross-Relaxation
7.2.1.3.
Distance Dependence
7.2.2.
Steady-State NOE
7.2.2.1.
Continuous Irradiation
7.2.2.2.
Enhancement Measurement
7.2.2.3.
Selective Experiments
7.2.3.
Transient NOE
7.2.3.1.
Pulse Sequences
7.2.3.2.
Time Evolution
7.2.3.3.
Mixing Times
7.2.4.
NOE Applications
7.2.4.1.
Stereochemical Assignment
7.2.4.2.
Conformational Analysis
7.2.4.3.
Proximity Determination
7.3.
Relaxation Time Measurements
7.3.1.
T₁ Measurement Techniques
7.3.1.1.
Inversion Recovery
7.3.1.2.
Saturation Recovery
7.3.1.3.
Progressive Saturation
7.3.2.
T₂ Measurement Techniques
7.3.2.1.
Spin Echo
7.3.2.2.
CPMG Sequence
7.3.2.3.
Line Shape Analysis
7.3.3.
Applications of Relaxation Data
7.3.3.1.
Molecular Dynamics
7.3.3.2.
Structure Determination
7.3.3.3.
Purity Assessment
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6. Integration and Quantitative Analysis
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8. Two-Dimensional NMR Spectroscopy