This course is an introduction to plasma phenomena, described using single-particle, fluid, and kinetic models. Prerequisites are calculus-based introductory courses (PHYS 111 and PHYS 112) and junior-level electromagnetic theory (PHYS 334 as concurrent or prerequisite).

The text used is F. F. Chen, __Introduction to Plasma Physics and Controlled Fusion__ Volume 1. Plasma Physics (Plenum Press, New York, 1984)

This course is a survey of plasma phenomena, described using single-particle, fluid and kinetic models. Prerequisite is a graduate-level course on electromagnetic theory (may be concurrent).

The text used is R. J. Goldston and P. H. Rutherford, __Introduction to Plasma Physics__ (Institute of Physics Publishing, Bristol, 1995)

This advanced course focuses on using plasma simulation to develop and refine one's physical understanding and intuition of phenomena encountered in plasma physics research. The course includes projects that involve actual simulating. Prerequisite is a graduate-level course on electromagnetic theory (may be concurrent) and PHYS 481 or PHYS 781.

The text used is C. K. Birdsall and A. B. Langdon, __Plasma Physics via Computer Simulation__ (Adam Hilger, New York, 1991)

This course focuses on advanced applications of kinetic theory to the study of plasmas and emphasizes the kinetic treatment of plasma waves. It covers the Vlasov equation, quasilinear theory, nonlinear phenomena, plasma waves and instabilities. Landau damping and finite-Larmor-radius effects. Prerequisites are PHYS 481 (Intro Plasma) & PHYS 631 (Graduate Classical â€¨Mechanics) & PHYS 634 (Graduate Electricity & Magnetism).

The typically recommended text used is P. M. Bellan, __Fundamentals of Plasma Physics__ (Cambridge University Press, 2008)

Ideal Magnetohydrodynamics (MHD) represents the simplest self-consistent model describing the macroscopic equilibrium and stability of plasma. This advanced course provides an in-depth introduction to this relatively mature theory within the field of plasma physics. Analytic theory is emphasized to develop a physical understanding of the ideal MHD model, to describe the equilibrium of various magnetic geometries, and to evaluate the stability properties of ideal MHD equilibria. Prerequisites are PHYS 481 (Intro Plasma) & PHYS 631 (Graduate Classical â€¨Mechanics) & PHYS 634 (Graduate Electricity & Magnetism).

Potential texts used are Arnab Rai Choudhuri __ The Physics of Fluids and Plasmas: An Introduction for Astrophysicists__ (Cambridge University Press, 1998); J. P. Friedburg __Ideal Magnetohydrodynamics__ (Plenum Press, New York, 1987); Ortolani and Schnack, __Magnetohydrodynamics of Plasma Relaxation__ (World Scientific Publishing Co. Pte. Ltd.,

New Jersey, 1993)