270075 VO Paramagnetism in Spectroscopy NMR, EPR and Hyperpolarization (2024S)
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Registration/Deregistration
Note: The time of your registration within the registration period has no effect on the allocation of places (no first come, first served).
Details
Language: English
Lecturers
Classes (iCal) - next class is marked with N
Thursday
11.04.
11:00 - 13:00
Seminarraum 2 Währinger Straße 38 Dekanat 1. Stock
Thursday
18.04.
10:45 - 12:45
Seminarraum 3 Organische Chemie 1OG Boltzmanngasse 1
Thursday
25.04.
10:45 - 12:45
Seminarraum 3 Organische Chemie 1OG Boltzmanngasse 1
Thursday
02.05.
10:45 - 12:45
Seminarraum 3 Organische Chemie 1OG Boltzmanngasse 1
Thursday
16.05.
10:45 - 12:45
Seminarraum 3 Organische Chemie 1OG Boltzmanngasse 1
Thursday
23.05.
10:45 - 12:45
Seminarraum 3 Organische Chemie 1OG Boltzmanngasse 1
N
Thursday
06.06.
10:45 - 12:45
Seminarraum 3 Organische Chemie 1OG Boltzmanngasse 1
Thursday
13.06.
10:45 - 12:45
Seminarraum 3 Organische Chemie 1OG Boltzmanngasse 1
Thursday
20.06.
10:45 - 12:45
Seminarraum 3 Organische Chemie 1OG Boltzmanngasse 1
Thursday
27.06.
10:45 - 12:45
Seminarraum 3 Organische Chemie 1OG Boltzmanngasse 1
Information
Aims, contents and method of the course
Assessment and permitted materials
Oral examn
Minimum requirements and assessment criteria
Basic knowledge of DNP, NMR and EPR spectroscopy and its applications according to the content of the lecture.Beurteilungsmaßstab:
100-87,5%: Very good (1)
87,4-75%: good(2)
74,9-62,5%: satisfactory (3)
62,4-50%: sufficient (4)
< 50%: not sufficient(5)
100-87,5%: Very good (1)
87,4-75%: good(2)
74,9-62,5%: satisfactory (3)
62,4-50%: sufficient (4)
< 50%: not sufficient(5)
Examination topics
Lecture contents and provided materials
Reading list
Electron Paramagnetic Resonance: Elementary Theory and Practical Applications, Second Edition, John A. Weil James R. Bolton, Wiley-VCH, 2006
Association in the course directory
BC-3, CHE II-3, CHE II-4, CH-SAS-02
Last modified: We 28.02.2024 13:47
The course will begin with an overview over the fundamentals behind the magnetic resonance of electron spins introducing the resonance phenomenon in general together with related topics such as electronic relaxation and the instrumentational setup of a magnetic resonance spectrometer.
Later, the use of unpaired electrons will be introduced on a wide spectrum of applications ranging from basic spin physics over bioinorganic chemistry to structural biology.
A special emphasis will be on the use of DNP for hyperpolarization, i.e. signal enhancement by in NMR.