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Last update: KFNTZT/MFF.CUNI.CZ (06.06.2019)
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Last update: KFNTZT/MFF.CUNI.CZ (06.06.2019)
Hore, P.J., Jones, J.A.; Wimperis, S.: NMR: the toolkit, Oxford University Press, 2000. Hore, P.J.: Nuclear magnetic resonance, Oxford University Press, 1995. Claridge, T.D.W.: High-resolution NMR techniques in organic chemistry, Elsevier, 2009. Levit, M.H.: Spin Dynamics, John Wiley & Sons, 2008. |
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Last update: KFNTZT/MFF.CUNI.CZ (06.06.2019)
Exam will consist of presenting solution of a homework project. The project is assigned at least 14 days prior examination and tests understanding principles of pulse experiments and spectra information content. |
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Last update: KFNTZT/MFF.CUNI.CZ (06.06.2019)
1. NMR phenomenon, NMR spectrum, NMR spectrometer. 2. Vector model and modern description of NMR, rotations and product operators. 3. NMR interactions and their manifestation n NMR spectra, interpretation of 1D spectra. 4. Polarization transfer, two-dimensional spectroscopy, experiments COSY, TOCSY, HSQC, HMQC, HMBC. 5. Spin relaxation, nuclear Overhauser effect, experiments IR, CPMG, NOESY, ROESY. 6. Chemical exchange. Translational diffusion. 7. Intermolecular interactions, chemical kinetics and stability constants, interpretation of relaxation. 8. Basics on solid-state NMR. |
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Last update: KFNTZT/MFF.CUNI.CZ (06.06.2019)
Contact the lecturer at the beginning of semester for actual schedule. |