×Toggle helper textThis website uses cookies. By using our website and agreeing to our cookies policy, you consent to our use of cookies in accordance with the terms of this policy. Read more
XWe have detected your location as outside the U.S/Canada, if you think this is wrong, you can choose your location.
With nearly 400 original illustrations, this NMR primer provides an introduction to solution NMR spectroscopy at a level appropriate for advanced undergraduates, graduate students and working scientists with backgrounds in...
With nearly 400 original illustrations, this NMR primer provides an introduction to solution NMR spectroscopy at a level appropriate for advanced undergraduates, graduate students and working scientists with backgrounds in chemistry or biochemistry. It presents the underlying physics and mathematics in a way that is both accessible and sufficiently complete to allow a real understanding of modern multi-dimensional experiments, thereby giving readers the tools they need to move to more advanced textbooks and articles.One special feature of this text is a thorough, but accessible, treatment of spin quantum mechanics, including scalar-coupled spins. A novel style of vector diagram is used to represent the quantum correlations between coupled spins and the manipulation of these correlations by pulses and time evolution. This will help to clarify what is arguably the most difficult aspect of NMR for students and practitioners to master.
With nearly 400 original illustrations, this NMR primer provides an introduction to solution NMR spectroscopy at a level appropriate for advanced undergraduates, graduate students and working scientists with backgrounds in chemistry or biochemistry.?
1. An Overview of Modern Solution NMR 2. An Introduction to Spin and Nuclear Magnetism 3. Early NMR Experiments 4. Chemical Information from Resonance Frequencies 5. The Pulse NMR Methods: The Pulse 6. The Pulse NMR Method: The Signal and Spectrum 7. Relaxation 8. A More Mathematical Look at Relaxation 9. Cross Relaxation and the Nuclear Overhauser Effect 10. Two-dimensional NMR Experiments 11. The Mathematical Formalism of Quantum Mechanics 12. More Quantum Mechanics: Time and Energy 13. Quantum Description of a Scalar-coupled Spin Pair 14. NMR Spectroscopy of a Weakly-coupled Spin Pair 15. Two-dimensional Spectra Based on Scalar Coupling 16. Heteronuclear NMR Techniques 17. Introduction to the Density Matrix 18. The Product-operator Formalism Appendix A: List of Symbols, Numerical Constants and Abbreviations Appendix B: Trigonometric Functions and Complex Numbers Appendix C: Fourier Series and Transforms Appendix D: Vectors and Matrices Appendix E: Mathematics for Uncoupled Spin-1/2 Particles Appendix F: Mathematics of the Two-spin System Index.
David P. Goldenberg is a Professor of Biology at the University of Utah, where he teaches and researches subjects in the general areas of biochemistry and biophysics, especially protein folding, dynamics and function. He received an A.B. degree in Chemistry and Mathematics from Whitman College in 1976 and a Ph.D. in Biology from the Massachusetts Institute of Technology in 1981. Before moving to the University of Utah, he was a post-doctoral associate at the Medical Research Laboratory of Molecular Biology, in Cambridge, England.
David P. Goldenberg is a Professor of Biology at the University of Utah, where he teaches and researches subjects in the general areas of biochemistry and biophysics, especially protein folding, dynamics and function. He received an A.B. degree in Chemistry and Mathematics from Whitman College in 1976 and a Ph.D. in Biology from the Massachusetts Institute of Technology in 1981. Before moving to the University of Utah, he was a post-doctoral associate at the Medical Research Laboratory of Molecular Biology, in Cambridge, England.
