Course syllabus

Magnetisk resonans - spektroskopi och avbildning
Magnetic Resonance - Spectroscopy and Imaging

KFKN01, 7,5 credits, A (Second Cycle)

Valid for: 2013/14
Decided by: Education Board C
Date of Decision: 2013-04-15

General Information

Elective for: B4-l, B5-l, B4-mb, B5-mb, K4-m, K5-m, K4-l, K5-l, N5-m
Language of instruction: The course will be given in English


The aim of the course is for the student to learn basic knowledge about Nuclear Magnetic Resonance (NMR) and its applications in the studies of molecular structure and dynamics and in imaging of materials and biological tissue.  The course treats methods for studying small molecules, macro molecules and colloidal systems, as well as solid materials.

Learning outcomes

Knowledge and understanding
For a passing grade the student must

Competences and skills
For a passing grade the student must

Judgement and approach
For a passing grade the student must


Lectures: The course begins with basic theory for Nuclear Magnetic Resonance, including an introduction to quantum mechanics. Then follow lectures on chemical shift, nuclear spin interactions, spin dynamics, chemical exchange, relaxation, multi-dimensional applications (including structure determination of macromolecules) and methods for imaging and the study of self-diffusion. The last part of the course is a possibility for each student to make a deeper descent into a subject that he or she finds interesting and relevant. A visit to the MR department at the Lund University Hospital might be offered.

Practicals: An introduction to the data treatment in NMR (including topics like the Fourier transform and artefacts) is followed by practicals covering chemical exchange, relaxation, imaging and self diffusion. An extra practical might be offered as a part of the student’s intensifying task. That practical might cover, for example, structure determination, solid state NMR or molecular dynamics.

Examination details

Grading scale: TH
Assessment: The final grade is based on a weighted average of the points achieved on the different course components. In order to pass the course, the student has to pass each of the different course components.

Code: 0114. Name: Midterm Examination.
Credits: 3. Grading scale: UG. Assessment: Written exam corresponding to 40% (3 points) of the total number of points awarded for the course. The result of the exam contributes 40% to the total grade point. Contents: Exam (midterm) covering those sections of the textbook and handouts that are included in the course. Further information: The midterm takes place during a scheduled class meeting.
Code: 0214. Name: Intensifying Task: Oral+Written Report.
Credits: 2,5. Grading scale: UG. Assessment: The test is evaluated based on all of the parts described below. The test result contributes 30% of the final grade. The test corresponds to 30% (2.25 points) of the total number of points awarded for the course. Contents: Written report on intensifying task. Oral presentation of intensifying task. Evaluation of fellow students written reports. Opposition on fellow students oral presentations.
Code: 0314. Name: Home Assignments.
Credits: 1. Grading scale: UG. Assessment: The home assignments correspond to 15% (1.125 points) of the total number of points awarded for the course. The result on the home assignments contributes 15% of the final grade. Contents: Written reports on home assignments. The course offers 4 weekly home assignments.
Code: 0414. Name: Laboratory Practicals.
Credits: 1. Grading scale: UG. Assessment: A written lab report should be handed in for each practical. These are evaluated and graded by the teachers. The total number of points contribute 15% to the final grade point. The lab practicals and reports correspond to 15% (1.125 points) of the total number of points awarded for the course. Contents: Laboratory practicals using computers and/or NMR-spectrometers: 3 practicals using NMR-spectrometer + 1 computer-based practical.


Required prior knowledge: Mathematics (analysis and linear algebra) and physical chemistry (thermodynamics, intermolecular interactions).
The number of participants is limited to: No
The course overlaps following course/s: KFK095

Reading list

Contact and other information

Course coordinator: Mikael Akke,
Course coordinator: Kristofer Modig,
Course homepage:
Further information: The course is also given as KEMM17 at the faculty of Science and is taught as a collaboration between the divisions of Biophysical Chemistry and Physical Chemistry. The two department share many years of experience with a multitude of different applications of the technique.