KE826: Spectroscopy (5 ECTS)

STADS: 10008901

Level
Master's level course

Teaching period
The course is offered in the autumn semester.

Teacher responsible
Email: mip@sdu.dk
Email: ilia@sdu.dk

Timetable
Group Type Day Time Classroom Weeks Comment
Common I Monday 10-12 U157 48
Common I Tuesday 14-16 U154 36,43,47-51
Common I Tuesday 14-16 U147 37,44,46
Common I Tuesday 14-16 U49b 38,41
Common I Tuesday 14-16 U10 39
Common I Tuesday 14-16 U156 40
Common I Tuesday 14-16 U20 45
Common I Wednesday 12-14 U10 50
Common I Thursday 08-10 U147 41
Common I Thursday 14-16 U147 44,47-49
Common I Thursday 12-14 U23a 45
Common I Thursday 10-12 U147 50-51
Common I Friday 13-15 U23a 43
Common I Friday 12-14 U146 46
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Prerequisites:
None

Academic preconditions:
Bachelor’s degree in Chemistry, Pharmaceutical Chemistry, Pharmaceutical Sciences, Nanobioscience or Chemical Engineering.

Additional prerequisites: KE503 Symmetry and KE524 Quantum Chemistry, alternatively KE818 Supplementary Course in Quantum Chemistry and Symmetry, are assumed known, or must be attended simultaneously, at the latest.

Course introduction
Aim of the course is to teach the students the theoretical background and applications of spectroscopy including techniques used for structural characterization in chemistry.

Expected learning outcome
At the end of the course the student is expected to be able to:

  • Classify molecules with regard to point group and rotor type.
  • Predict electronic spectra for diatomic molecules and rotational and vibrational spectra for selected classes of molecules from molecular symmetry and selection rules
  • Do calculations involving the relation between rotational spectra and molecular structure
  • Calculate the distribution of normal modes of vibrations in the various symmetry species and predict the spectral activity
  • Determine the electronic configuration and term symbol for diatomic and polyatomic molecules and to apply electronic selection rules
  • Identify and analyse 1st and 2nd order spin systems
  • Analyse simple pulse sequences using the vector model
  • Describe the principles of relaxation
  • Explain the principles of 2D NMR spectroscopy and possess knowledge of the most common 2D NMR pulse sequences
  • Apply NMR spectroscopy to obtain structural information
Subject overview
  • Optical spectroscopy
    o Experimental methods and theoretical background for rotational, vibrational and electronic spectroscopy
    o Rotational-, vibrational- and electron spectroscopy applied to the study of molecular structure and dynamics
  • NMR spectroscopy o Spin systems, strong and weak coupling, including AB and ABX
    o Relaxation, NOE and dynamic NMR
    o Pulse sequences and the vector model
    o Principles of 2D NMR and its applications
    o NMR of “other” nuclei, including 15N and 31P
    • One project
Literature
  • Meddeles senere.: .
  • Horst Friebolin: Basic One- and Two-Dimensional NMR Spectroscopy, Wiley-VCH.ISBN-nr.: 978-3-527-31233.


Website
This course uses e-learn (blackboard).

Prerequisites for participating in the exam
None

Assessment and marking:
  1. 2 small pProject reports. Passed/not passed, internal marking by lecturer. Approval of the projects is a prerequisite for participating in the written exam. (10008912)
  2. A 4 hour written digital exam with books and notes of your own choice. Internet access is not allowed. Danish 7-point marking scale, external examiner. (10008902)

Reexamination in the same exam period or immediately thereafter.



Expected working hours
The teaching method is based on three phase model.
Intro phase: 20 hours
Skills training phase: 30 hours, hereof:
 - Tutorials: 30 hours

Educational activities Study phase: 80 hours

Language
This course is taught in English, if international students participate. Otherwise the course is taught in Danish.

Course enrollment
See deadline of enrolment.

Tuition fees for single courses
See fees for single courses.