Electromagnetic Waves for Thermonuclear Fusion Research

The science of magnetically confined plasmas covers the entire spectrum of physics from classical and relativistic electrodynamics to quantum mechanics. During the last sixty years of research, our initial primitive understanding of plasma physics has made impressive progress thanks to a variety of experiments — from tabletop devices with plasma temperatures of a few thousands of degrees and confinement times of less than 100 microseconds, to large tokamaks with plasma temperatures of up to five hundred million degrees and confinement times approaching one second. We discovered that plasma confinement is impaired by a variety of instabilities leading to turbulent processes with scales ranging from the plasma size to a few millimeters. Understanding these phenomena, which have slowed down progress towards a fusion reactor, requires the use of very sophisticated diagnostic tools, many of which employ electromagnetic waves.

The primary objective of this book is to discuss the fundamental physics upon which the application of electromagnetic waves to the study of magnetically confined plasmas is based.
Contents:

Controlled Thermonuclear Fusion
Electron Waves
Inhomogeneous Plasmas
Refractive Index Measurements
Wave Propagation in Turbulent Plasmas
Non-Collective Scattering
Plasma Reflectometry
Electron Cyclotron Waves in Hot Plasmas
Electron Cyclotron Emission



Readership: Advanced students and professionals who are interested in thermonuclear plasmas.