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FJD3300 Kinetic Plasma Theory 6.0 credits

Administer About course

This course introduces, from first principles, the kinetic theory of plasma. Specifically, the following topics are studied:
• theoretical basis
• basic instabilities and collisional effects
• kinetic plasma models
• kinetic instabilities

Information per course offering

Termin

Information for Spring 2025 Start 17 Mar 2025 programme students

Course location

KTH Campus

Duration
17 Mar 2025 - 2 Jun 2025
Periods
P4 (6.0 hp)
Pace of study

33%

Application code

61194

Form of study

Normal Daytime

Language of instruction

English

Course memo
Course memo is not published
Number of places

Places are not limited

Target group
No information inserted
Planned modular schedule
[object Object]
Schedule
Schedule is not published
Part of programme
No information inserted

Contact

Examiner
No information inserted
Course coordinator
No information inserted
Teachers
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Course syllabus as PDF

Please note: all information from the Course syllabus is available on this page in an accessible format.

Course syllabus FJD3300 (Spring 2019–)
Headings with content from the Course syllabus FJD3300 (Spring 2019–) are denoted with an asterisk ( )

Content and learning outcomes

Course contents

Liouvilles theorem. BBGKY hierarchy. Vlasov and Boltzmann equations. Plasma dispersion function. Landau damping. The bump-on-tail instability. Criteria of Nyquist and Penrose. Bernstein modes. The Fokker-Planck equation. Relaxation times. Resistivity. Chapman and Enskog expansions. Drift-kinetic model. Gyrokinetic model. Gyrofluid model. Vlasov-Fluid hybrid model. Two-stream instability. Inverse Landau damping. Collisionless drift waves. Electron and ion temperature gradient instabilities. Loss-cone instability.

Intended learning outcomes

When completing the course, the student should be able to

  • Derive the basic plasma kinetic equation from first principles
  • Discuss applications and validity of the Vlasov and Boltzmann equations
  • Describe and explain Landau damping and the two-stream instability
  • Describe basic kinetic properties of hot magnetised plasmas
  • Derive and explain the Fokker-Planck equation
  • Describe basic relaxation processes and collision times
  • Distinguish between fully kinetic, drift kinetic, hybrid and gyrofluid models

Literature and preparations

Specific prerequisites

Master in Electrical Engineering or Engineering Physics or similar.

Recommended prerequisites

Master in Electrical Engineering or Engineering Physics or similar.    

Literature

You can find information about course literature either in the course memo for the course offering or in the course room in Canvas.

Examination and completion

If the course is discontinued, students may request to be examined during the following two academic years.

Grading scale

P, F

Examination

  • EXA1 - Examination, 6.0 credits, grading scale: P, F

Based on recommendation from KTH’s coordinator for disabilities, the examiner will decide how to adapt an examination for students with documented disability.

The examiner may apply another examination format when re-examining individual students.

Other requirements for final grade

Participation in group discussions, completion of home assignments and oral exam.

Examiner

Profile picture Mathias Hoppe

Ethical approach

  • All members of a group are responsible for the group's work.
  • In any assessment, every student shall honestly disclose any help received and sources used.
  • In an oral assessment, every student shall be able to present and answer questions about the entire assignment and solution.

Further information

Course room in Canvas

Registered students find further information about the implementation of the course in the course room in Canvas. A link to the course room can be found under the tab Studies in the Personal menu at the start of the course.

Offered by

EECS/Fusion Plasma Physics

Main field of study

This course does not belong to any Main field of study.

Education cycle

Third cycle

Supplementary information

Course main content: 

Liouvilles theorem. BBGKY hierarchy. Vlasov and Boltzmann equations. Plasma dispersion function. Landau damping. The bump-on-tail instability. Criteria of Nyquist and Penrose. Bernstein modes. The Fokker-Planck equation. Relaxation times. Resistivity. Chapman and Enskog expansions. Drift-kinetic model. Gyrokinetic model. Gyrofluid model. Vlasov-Fluid hybrid model. Two-stream instability. Inverse Landau damping. Collisionless drift waves. Electron and ion temperature gradient instabilities. Loss-cone instability.

Learning outcomes:

When completing the course, the student should be able to

  • Derive the basic plasma kinetic equation from first principles
  • Discuss applications and validity of the Vlasov and Boltzmann equations
  • Describe and explain Landau damping and the two-stream instability
  • Describe basic kinetic properties of hot magnetised plasmas
  • Derive and explain the Fokker-Planck equation
  • Describe basic relaxation processes and collision times
  • Distinguish between fully kinetic, drift kinetic, hybrid and gyrofluid models

Postgraduate course

Postgraduate courses at EECS/Fusion Plasma Physics