Plasma theory
Course: Applied Physics and Nanomaterials
Structural unit: Faculty of Radiophysics, Electronics and Computer Systems
Title
Plasma theory
Code
ВБ 3.1
Module type
Вибіркова дисципліна для ОП
Educational cycle
Second
Year of study when the component is delivered
2023/2024
Semester/trimester when the component is delivered
3 Semester
Number of ECTS credits allocated
4
Learning outcomes
Development of students' ability to apply the kinetic approach to the description of plasmas. Formation of an in-depth unifying view on various plasma phenomena such as eigenwaves, Coulomb collisions between charged particles, particle-wave interaction, nonlinear wave interaction.
Form of study
Full-time form
Prerequisites and co-requisites
The academic discipline "Plasma Theory" is based on the courses "Statistical Physics", "Electricity and Magnetism", "Differential Equations", "Mathematical Physics".
Course content
Basic concepts of plasma physics. Plasma parameter, fluid limit. Ideal and non-ideal plasma. Charge shielding and plasma oscillations.
Kinetic description of plasma. The Vlasov equation. Equation for the field in plasma. Eigenwaves. Dielectric permittivity of isotropic plasma. Dispersion relation for potential and electromagnetic waves. The condition of weak wave damping. Langmuir, ion-sound and electromagnetic waves. Damping of waves in a collisionless plasma, undamped oscillations of the distribution function and the echo phenomenon.
Equations of hydrodynamics, their connection with the Vlasov equation. The difference between kinetic and hydrodynamic descriptions of plasma.
Plasma in a constant uniform magnetic field. Cyclotron harmonics. Bernstein waves. Dependence of the refractive index on the wave frequency. Cutoff points and resonances, plasma heating by electromagnetic waves.
Weak turbulence, collision of particles with turbulent fields. Quasilinear theory of kinetic beam instability, formation of a plateau on a distribution function.
Coulomb collisions. The Balescu - Lenard collision integral.
Nonlinear equation for a field in plasma. Nonlinear susceptibilities. Hierarchy of time scales, elimination of secularities, slow variation of wave amplitudes. Three-wave and four-wave resonant interactions. Decay and explosive instabilities. Nonlinear frequency shift of plasma oscillations, saturation of instabilities.
Recommended or required reading and other learning resources/tools
1.Загороднiй А.Г., Момот А.I. Вступ до теорії плазми, Київ – 2015.
2. Анісімов І.О. Фізика плазми, Київ – 2018.
3. Ситенко А.Г. Флуктуации и нелинейное взаимодействие волн в плазме, К.: Наук. думка, 1977.
4. Wesson J. Tokamaks - Oxford, Calderon Press, 2004.
5. Ситенко О.Г., Мальнєв В.М. Основи теорії плазми. К., Наукова думка, 1994.
6. І.О.Анісімов. Фізика плазми. Конспект лекцій. К., 2018.
Planned learning activities and teaching methods
Lectures, solving of problems, student reports on topics, exam.
Assessment methods and criteria
Problem solving, student reports, and exam answers are evaluated. The grade has the following components: knowledge up to 45%; skill - up to 45%; clarity of presentation - up to 10%.
Language of instruction
Ukrainian
Lecturers
This discipline is taught by the following teachers
Volodymyr
Zasenko
Department of Electron Physics
Faculty of Radiophysics, Electronics and Computer Systems
Faculty of Radiophysics, Electronics and Computer Systems
Departments
The following departments are involved in teaching the above discipline
Department of Electron Physics
Faculty of Radiophysics, Electronics and Computer Systems