High-Resolution NMR Techniques in Organic Chemistry, Third Edition describes the most important NMR spectroscopy techniques for the structure elucidation of organic molecules and the investigation of their behaviour in solution. Appropriate for advanced undergraduate and graduate students, research chemists and NMR facility managers, this thorough revision covers practical aspects of NMR techniques and instrumentation, data collection, and spectrum interpretation. It describes all major classes of one- and two-dimensional NMR experiments including homonuclear and heteronuclear correlations, the nuclear Overhauser effect, diffusion measurements, and techniques for studying protein–ligand interactions. A trusted authority on this critical expertise, High-Resolution NMR Techniques in Organic Chemistry, Third Edition is an essential resource for every chemist and NMR spectroscopist.
|Edition description:||New Edition|
|Product dimensions:||8.50(w) x 10.87(h) x (d)|
About the Author
Tim Claridge has over 25 years of practical experience in NMR Spectroscopy and is presently Professor of Magnetic Resonance and Director of NMR Spectroscopy for Organic Chemistry and Chemical Biology in the Department of Chemistry at the University of Oxford. His interest in NMR was ignited as an undergraduate student of Chemistry and Analytical Science whilst undertaking a year-long industrial placement in the spectroscopy laboratory of a leading pharmaceutical company. He subsequently completed a DPhil in protein NMR spectroscopy under the supervision of the late Andy Derome in the Dyson Perrins Laboratory at the University of Oxford. He then remained in Oxford and was appointed manager of the organic chemistry NMR facilities and in this capacity co-authored the undergraduate text "Introduction to Organic Spectroscopy (OUP)" with Prof Laurence Harwood and produced the first edition of "High-Resolution NMR Techniques in Organic Chemistry" (Pergamon Press). He became University Research Lecturer (Reader) in 2006, and was made a full Professor and a Fellow of the Royal Society of Chemistry (RSC) in 2014. He served for many years on the RSC NMR Discussion Group committee including as its Chairman for three years. He has co-authored over 170 research papers and his research interests focus broadly on the application of solution-state NMR methods for characterizing small molecules, and for studying their behavior and their interactions, especially as ligands for biological macromolecules.
Table of Contents
Preface 1 Introduction 2 Introducing High-Resolution NMR 3 Practical Aspects of High-Resolution NMR 4 One-Dimensional Techniques 5 Introducing Two-Dimensional and Pulsed Field Gradient NMR 6 Correlations Through the Chemical Bond I: Homonuclear Shift Correlation 7 Correlations Through the Chemical Bond II: Heteronuclear Shift Correlation 8 Separating Shifts and Couplings: J-Resolved and Pure Shift Spectroscopy 9 Correlations Through Space: The Nuclear Overhauser Effect 10 Diffusion NMR Spectroscopy 11 Protein–Ligand Screening by NMR 12 Experimental Methods 13 Structure Elucidation and Spectrum Assignment Appendix Subject Index