Type of course

The course is available as a singular course. Please contact the administration at the Faculty of Science and Technology, att. PhD education.

Programstudents may register for the course through Studentweb. The registration deadline is September 1st/February 1st.

Other PhD students at UiT and external applicants may apply for admission through Søknadsweb, application code 9301. The application deadline is June 1st for the autumn semester and December 1st for the spring semester.

Admission requirements

Programstudents may register for the course through Studentweb. The registration deadline is September 1st/February 1st.

Other PhD students at UiT and external applicants may apply for admission through Søknadsweb, application code 9301. The application deadline is June 1st for the autumn semester and December 1st for the spring semester.

PhD students or holders of a Norwegian master´s degree of five years or three + two years (or equivalent) may be admitted. Only students with a background in physics, or another discipline which provides the student with the relevant knowledge, may be admitted. Students are expected to have skills equivalent to the prerequisites listed for the course.

PhD students are exempt from semester fee.

All external applicants have to attach a confirmation of their status as a PhD student from their home institution. Students who hold a Master of Science degree, but are not yet enrolled as a PhD-student have to attach a copy of their master's degree diploma. These students are also required to pay the semester fee.

More information regarding PhD courses at the Faculty of Science and Technology is found here.

The course will only be taught if there is a sufficient number of students.

Course content

Recommended prerequisites

Objectives of the course

Knowledge - The student will be able to:

• describe the principles of fusion processes, energy confinement, power balance, and the basic design of a fusion power reactor
• give an in depth explations on the principles of magnetic confinement of plasmas, in particular the Tokamak and Stellarator concepts
• describe equilibrium and stability of magnetically confined plasmas
• identify causes of particle and heat transport in magnetically confined plasmas
• describe the power and particle exhaust and the role of plasma-wall interactions

Skills - The student will be able to:

• obtain and interpret relevant new theories about magnetic confinement, heating, stability and transport
• analyze and interpret data from experimental measurements and numerical simulations
• solve problems in fluid and plasma dynamics using analytical and numerical methods

General expertise - The student will be able to:

• incorporate current events and new scientific information into a critical thinking
• communicate theories, problem descriptions and solutions

Language of instruction and examination

Teaching methods

Lectures: 40 hours

Exercises: 24 hours