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Magnetic and electric resonance /
This book is devoted to a quasi-classical treatment of quantum transitions, with an emphasis on nuclear magnetic resonance, nuclear quadrupole resonance and electric dipolar resonance. The method described here is based on the quasi-classical description of condensed matter, and makes use of the equ...
| Clasificación: | Libro Electrónico |
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| Autor principal: | |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
Newcastle upon Tyne, UK :
Cambridge Scholars Publishing,
2018.
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| Temas: | |
| Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Intro; Contents; 1 Preface; 2 Introduction; 3 Electric and Magnetic Moments; 3.1 Electric dipole and quadrupole moments; 3.2 Magnetic Moments; 3.3 Atoms and molecules; 3.4 Atomic moments; 3.5 Atomic nucleus and nuclear moments; 3.6 Hyperfine splitting in molecules; 3.7 Atomic polarizability; 3.8 Molecular polarizability: orientational; 3.9 Molecular polarizability: vibrational; 3.10 Polarization of matter; 3.11 A fourth kind of polarization; 3.12 Polarized sphere; 3.13 Magnetization in Matter; 3.14 Diamagnetism; 3.15 Paramagnetism; 3.16 Molecular paramagnetism; 3.17 Magnetism in metals
- 3.18 Ferromagnetism4 Classical Limit; 4.1 Electromagnetic field; 4.2 Matter; 4.3 Perturbations and transitions; 4.4 Orientational polarizability; 4.5 Absorption and emission of radiation; 4.6 Motion of magnetization; 4.7 A quasi-classical note; 4.8 Macroscopic motion; 5 Magnetic Resonance I; 5.1 Nuclear magnetic resonance; 5.2 Emitted field; 5.3 Line width; 5.4 Hyperfine splitting; 5.5 Ferromagnetic resonance; 5.6 Classical quasi-particles; 5.7 Quasi-classical dynamics; 5.8 Nuclear quadrupole resonance; 5.9 Quantum transitions; 5.10 Quasi-quantum mechanical dynamics
- 5.11 A parametrization for the NQR6 Electric Dipolar Resonance; 6.1 Quasi-classical dynamics; 6.2 Vibration resonance; 6.3 Quasi-classical dynamics; 6.4 Rotation resonance. Planar rotator; 6.5 Rotation resonance. Spherical pendulum; 6.6 Rotation resonance. Quenched dipoles; 6.7 Parametric resonance; 6.8 Parametric resonance. Quenched dipoles; 7 Parametric Resonance in Rotation Molecular Spectra; 7.1 Summary and introduction; 7.2 Free rotations; 7.3 Strong static field; 7.4 Weak static field; 7.5 Dipolar interaction; 7.6 Discussion and conclusions; 7.7 Highly-oscillating electric fields
- 7.8 Appendix8 Magnetic Resonance II; 8.1 Classical magnetic moments; 8.2 Magnetic moments of the particles; 8.3 Nuclear magnetic resonance; 8.4 Emitted field; 8.5 Line width; 8.6 Hyperfine splitting; 8.7 Ferromagnetic resonance; 8.8 Quasi-classical dynamics; 8.9 Electric dipole and quadrupole moments; 8.10 Nuclear quadrupole resonance; 8.11 Spin echo; 9 ""Exact"" solutions; 9.1 A general case; 9.2 Right angles. Nuclear magnetic resonance; 9.3 Nuclear quadrupole resonance; 9.4 Parametric interaction; 9.5 Spectral line; 9.5.1 Introduction; 9.5.2 Zeeman splitting and transverse excitation
- 9.5.3 Arbitrary orientation9.5.4 Conclusion; 10 Concluding Chapter; 10.1 Summary and introduction; 10.2 Quasi-classical dynamics. Quantum systems; 10.3 Example 1. Planar rotator; 10.4 Example 2. Spherical pendulum; 10.5 Extension to condensed matter; 10.6 Example 3. Nuclear magnetic resonance; 10.7 Example 4. Nuclear quadrupole resonance; 10.8 Discussion and conclusions; 11 Epilogue; 11.1 Introduction; 11.2 Old Quantum Mechanics; 11.3 Matricial Quantum Mechanics; 11.4 Wave Mechanics; 11.5 Additional remarks; 11.6 Fundamental experiments; 11.7 Concluding remarks; 12 References; Index