Principles of Magnetic Resonance
Slichter, Charles P.
Principles of Magnetic Resonance [electronic resource] / by Charles P. Slichter. - 3rd ed. 1990. - Berlin, Heidelberg : Springer Berlin Heidelberg : Imprint: Springer, 1990. - XII, 658 p. online resource.
1. Elements of Resonance -- 2 Basic Theory -- 3. Magnetic Dipolar Broadening of Rigid Lattices -- 4. Magnetic Interactions of Nuclei with Electrons -- 5. Spin-Lattice Relaxation and Motional Narrowing of Resonance Lines -- 6. Spin Temperature in Magnetism and in Magnetic Resonance -- 7. Double Resonance -- 8. Advanced Concepts in Pulsed Magnetic Resonance -- 9. Multiple Quantum Coherence -- 10. Electric Quadrupole Effects -- 11. Electron Spin Resonance -- 12. Summary -- Problems -- Appendixes -- A. A Theorem About Exponential Operators -- B. Some Further Expressions for the Susceptibility -- D. A Theorem from Perturbation Theory -- E. The High Temperature Approximation -- F. The Effects of Changing the Precession Frequency - Using NMR to Study Rate Phenomena -- G. Diffusion in an Inhomogeneous Magnetic Field -- H. The Equivalence of Three Quantum Mechanics Problems -- I. Powder Patterns -- J. Time-Dependent Hamiltonians -- K. Correction Terms in Average Hamiltonian Theory - The Magnus Expansion -- Selected Bibliography -- References -- Author Index.
This is a textbook intended for graduate students who plan to work in nuclear magnetic resonance or electron spin resonance. The text describes the basic principles of magnetic resonance, steady-state and pulse methods, the theory of the width, shape and position of spectral absorption lines as well as the theory of relaxation times. It also introduces the density matrix. This third edition adds new material to many parts, plus new sections on one- and two-dimensional Fourier transform methods, multiple quantum coherence and magnetic resonance imaging.
9783662094419
Spectrum analysis.
Condensed matter.
Magnetism.
Atoms.
Molecules.
Lasers.
Quantum optics.
Spectroscopy.
Condensed Matter Physics.
Magnetism.
Atomic, Molecular and Chemical Physics.
Laser.
Quantum Optics.
543
Principles of Magnetic Resonance [electronic resource] / by Charles P. Slichter. - 3rd ed. 1990. - Berlin, Heidelberg : Springer Berlin Heidelberg : Imprint: Springer, 1990. - XII, 658 p. online resource.
1. Elements of Resonance -- 2 Basic Theory -- 3. Magnetic Dipolar Broadening of Rigid Lattices -- 4. Magnetic Interactions of Nuclei with Electrons -- 5. Spin-Lattice Relaxation and Motional Narrowing of Resonance Lines -- 6. Spin Temperature in Magnetism and in Magnetic Resonance -- 7. Double Resonance -- 8. Advanced Concepts in Pulsed Magnetic Resonance -- 9. Multiple Quantum Coherence -- 10. Electric Quadrupole Effects -- 11. Electron Spin Resonance -- 12. Summary -- Problems -- Appendixes -- A. A Theorem About Exponential Operators -- B. Some Further Expressions for the Susceptibility -- D. A Theorem from Perturbation Theory -- E. The High Temperature Approximation -- F. The Effects of Changing the Precession Frequency - Using NMR to Study Rate Phenomena -- G. Diffusion in an Inhomogeneous Magnetic Field -- H. The Equivalence of Three Quantum Mechanics Problems -- I. Powder Patterns -- J. Time-Dependent Hamiltonians -- K. Correction Terms in Average Hamiltonian Theory - The Magnus Expansion -- Selected Bibliography -- References -- Author Index.
This is a textbook intended for graduate students who plan to work in nuclear magnetic resonance or electron spin resonance. The text describes the basic principles of magnetic resonance, steady-state and pulse methods, the theory of the width, shape and position of spectral absorption lines as well as the theory of relaxation times. It also introduces the density matrix. This third edition adds new material to many parts, plus new sections on one- and two-dimensional Fourier transform methods, multiple quantum coherence and magnetic resonance imaging.
9783662094419
Spectrum analysis.
Condensed matter.
Magnetism.
Atoms.
Molecules.
Lasers.
Quantum optics.
Spectroscopy.
Condensed Matter Physics.
Magnetism.
Atomic, Molecular and Chemical Physics.
Laser.
Quantum Optics.
543