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Advances in Magnetic Resonance
Volume 2
1st Edition - January 1, 1966
Editor: John S. Waugh
eBook ISBN:9781483281490
9 7 8 - 1 - 4 8 3 2 - 8 1 4 9 - 0
Advances in Magnetic Resonance, Volume 2, features a mixture of experimental and theoretical contributions. The book contains four chapters and begins with an ambitious and… Read more
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Advances in Magnetic Resonance, Volume 2, features a mixture of experimental and theoretical contributions. The book contains four chapters and begins with an ambitious and general treatment of the problem of signal-to-noise ratio in magnetic resonance. This is followed by separate chapters on the interpretation of nuclear relaxation in fluids, with special reference to hydrogen; and various aspects of molecular theory of importance in NMR.
Contributors
Preface
Contents of Previous Volumes
Tentative Contents of Future Volumes
Sensitivity Enhancement in Magnetic Resonance
I. Introduction
II. Methods to Improve the Sensitivity
III. The Information Processor
IV. Optimum Timing of Magnetic Resonance Experiments
Appendix A. Definition of the Fourier Transform
Appendix B. Some Remarks about Linear Filters
Appendix C. Some Remarks about Random Noise
Appendix D. Measurement of the Signal-to-Noise Ratio
Appendix E. Calculation of Optimum Filters
Appendix F. Intermediate Passage Region
Appendix G. Conditions for Adiabatic Passage in Liquids and Gases
The Chemical Shift and Other Second-Order Magnetic and Electric Properties of Small Molecules
I. Introduction
II. The Bound Proton in a Strongly Separated Molecular Ground State
III. Proton Shielding in Transition Metal Hydride Complexes
IV. General Theory of Chemical Shift
Appendix A. Molecular Self-Consistent Field Theory for Unperturbed Molecules
Appendix B. Perturbed (or Coupled) Self-Consistent Field Theory
Theory of the Chemical Shift
I. Introduction
II. General Theory
III. Calculations
IV. Discussion
Appendix A. The Current Density Procedure and Pseudofields
Appendix B. The Magnetic Susceptibility of a Cyclic Molecule an London's Procedure
Nuclear Relaxation in Hydrogen Gas and Liquid
I. Introduction
II. Qualitative Discussion of H2 Relaxation
III. Relaxation Theory
IV. Evaluation of the Lattice Correlation Functions
V. Interpretation of the Experimental H2 Gas Data
VI. Interpretation of the Experimental Adulterated H2 Gas Data
VII. Interpretation of the Experimental H2 Liquid Data