MAGNETOHYDRODYNAMICS AND PLASMA PHYSICS

Academic Year 2018/2019 - 1° Year - Curriculum ASTROPHYSICS
Teaching Staff: Francesca ZUCCARELLO
Credit Value: 6
Taught classes: 42 hours
Term / Semester:

Learning Objectives

The course is aimed at providing the student the basic knowledge and the state of the art of some topics in Magnetohydrodynamics and Plasma Physics: deepened knowledge of laws of electromagnetism; knowledge of the motions of charged particles in presence of magnetic, electric or other force fields; knowledge of the concept and of the properties of plasma; magnetohydrodynamics approach; frozen magnetic fields; knowledge of 2D and 3D reconnection mechanisms.


Course Structure

Teaching is based on lectures.


Detailed Course Content

Program of the course

Electric and magnetic fields: The electromagnetic field. Potential magnetic field. The scalar electric potential. Faraday induction equation. Dipolar magnetic field. The interplanetary magnetic field.

Plasma Physics: Plasma definition. Concept of temperature of a plasma. Debye distance. Plasma oscillations. Parameters that characterize a plasma. Diffusion in a plasma. Collisional and non-collisional plasma. Plasma kinetic description. Distribution function. Moments of the distribution function. Vlasov equation.

Theory of orbits: Van Allen Radiation belts. Lorentz force. Motion of particles and motion of the guiding center. Motion of a particle in a constant magnetic field. Magnetic moment. Mirror points. Adiabatic invariants.

Magnetohydrodynamic equations: Eulerian and Lagrangian points of view. Forces acting on a fluid. Continuity equation. Equation of motion. Equation of energy conservation. System of equations of the MHD. Induction equation. Magnetic Reynolds number. Decay of the magnetic field in absence of motion. Evolution of the magnetic field in presence of motion of the fluid and with an infinite conductivity. Conservation law of the magnetic flux. Law of the frozen magnetic field.

Magnetic reconnection: Neutral points. Current sheets. Sweet Parker model. Petschek model. Tearing mode instability. Coalescence instability. 3D magnetic reconnection.


Textbook Information

  • C. Chiuderi & M. Velli: Fisica del Plasma: Fondamenti e applicazioni astrofisiche, Springer - Verlag, 2012
  • D.A. Gurnett & A. Bhattacharjee: Introduction to Plasma Physics, Cambridge University Press, 2005
  • E.N. Parker, Cosmical Magnetic Fields, Clarendon Press – Oxford, 1979
  • E. R. Priest : Solar magnetohydrodynamics, Reidel Publ. Co., Dordrecht, 1984
  • R.M. Kulsrud: Plasma Physics for Astrophysics, Princeton University Press, 2005