Advances in Magnetic Resonance
Volume 11
- 1st Edition - January 1, 1983
- Latest edition
- Editor: John S. Waugh
- Language: English
Advances in Magnetic Resonance, Volume 11, presents a variety of contributions to the theory and practice of magnetic resonance. The book contains three chapters and begins with a… Read more
Data Mining & ML
Unlock the cutting edge
Up to 20% on trusted resources. Build expertise with data mining, ML methods.
Description
Description
Advances in Magnetic Resonance, Volume 11, presents a variety of contributions to the theory and practice of magnetic resonance. The book contains three chapters and begins with a discussion of the principles and applications of dynamic nuclear polarization, with emphasis on molecular motions and collisions, intermolecular couplings, and chemical interactions. Subsequent chapters focus on the assessment of a proposed broadband decoupling method and studies of time-domain (or Fourier transform) multiple-quantum nuclear magnetic resonance.
Table of contents
Table of contents
Contributors
Preface
Contents of Previous Volumes and Supplements
Molecular Motions and Interactions as Studied by Dynamic Nuclear Polarization (DNP) in Free Radical Solutions
I. Introduction
II. Theoretical and Experimental Considerations
III. Experimental Results: Enhancements and Intermolecular Hyperfine Interactions
IV. Multifield Measurements and Spectral Density Curves
V. Conclusions
List of Symbols
Broadband Decoupling in High-Resolution Nuclear Magnetic Resonance Spectroscopy
I. Introduction
II. Theory
III. Computer Simulations
IV. Experimental
V. Discussion
Appendix. High-Order Hamiltonians for Cyclically Permuted Cycles
Time-Domain Multiple-Quantum NMR
I. Introduction
II. Fundamental Principles and Phenomena
III. Excitation Dynamics for Many-Level Systems
IV. Multiple-Quantum Processes with Two Spin Species
V. Relaxation
Index
Product details
Product details
- Edition: 1
- Latest edition
- Published: August 28, 1983
- Language: English
View book on ScienceDirect
View book on ScienceDirect
Read Advances in Magnetic Resonance on ScienceDirect