After successfully completing the course you will:
- be able to analyse magnetic resonance spectra on the basis of the quantum mechanical as well as the classical description of magnetic resonance.
- have acquired some basic skill in carrying out NMR measurements and gained some basic understanding of NMR spectrometer operation.
- be acquainted with the various fields within magnetic resonance and be able to indicate the relevant interactions and specific experiments and characteristics for each field.
Magnetic resonance techniques have a broad range of application in chemistry, physics, biochemistry materials science and medicine This lecture course covers the basics of magnetic resonance spectroscopy as well as applications of this important technique. First, the theoretical framework of magnetic resonance is covered in the lectures. The theory is covered both from a classical as well as the quantummechanical viewpoint.
The practical part is intended to illustrate the material covered in the lectures and workshops. After the theoretical framework is covered, various fields within magnetic resonance are discussed among which are: solid state NMR, electron spin resonance, magnetic resonance imaging (MRI) and biomolecular NMR, as well as applications in organic and inorganic chemistry.
|This course is taught in English|
|• Bloch equations|
• Rotating frame
• Angular momentum
• Spin operators
• Spin Hamiltonian
• Spectral assignment
• Biomolecular NMR
• Vaste Stof NMR
• Dynamic processes
|Written exam (80%), computer practical and report (10%) and practical work and report (10%). Each of the 3 components have to be passed individually in order to pass the entire course.|
|Quantummechanica 1 (NWI-MOL041) en 2 (NWI-MOL046), Chemische analyse (NWI-MOL001), and Spectroscopische technieken (NWI-MOL019).This is a course in the theme 'Methods'.|
• O.Zerbe and S.Jurt, Applied NMR Spectroscopy for Chemists and Life Scientists, Wiley; ISBN: 9783527327744
• M.A. Levitt, Spin dynamics: basics of Nuclear Magnetic Resonance, Wiley 2nd ed., ISBN: 0470511176
• J. Keeler, Understanding NMR Spectroscopy, Wiley 2nd ed., ISBN 0470746080
• R.K. Harris, Nuclear Magnetic Resonance Spectroscopy
• P.J. Hore, Nuclear Magnetic Resonance, Oxford Chemistry Primer, ISBN: 0198556829
• R.S. Macomber, A complete introduction to modern NMR spectroscopy, ISBN: 0471157368
These books are present in the library.
• 8 hours computer course
• 32 hours lecture
• 8 hours laboratory course
• 32 hours problem session
• 88 hours individual study period
|O.Zerbe and S.Jurt, Applied NMR Spectroscopy for Chemists and Life Scientists, Wiley. This book is available in the library|
|M.A. Levitt, Spin dynamics: basics of Nuclear Magnetic Resonance, Wiley 2nd ed. This book is available in the library|
|J. Keeler, Understanding NMR Spectroscopy, Wiley 2nd ed. This book is available in the library|
|R.K. Harris, Nuclear Magnetic Resonance Spectroscopy. This book is available in the library|
|P.J. Hore, Nuclear Magnetic Resonance, Oxford Chemistry Primer. This book is available in the library|
|R.S. Macomber, A complete introduction to modern NMR spectroscopy. This book is available in the library|
|Gelegenheden||Blok KW1, Blok KW2|