Preface
1 Prelude to volume two
2 Effects of the electron temperature
3 Effects of the ion temperature
4 Lagrangian field theory and drifts
5 Introduction to gyrokinetic theory
6 Phase space and energetic consistency
7 Gyrokinetic theory for local dynamics
8 Gyrokinetic treatment of waves
9 Introduction to gyrofluid theory
10 Gyrofluid equations for thermal dynamics
11 Gyrofluid Drift-Alfven turbulence
12 Electron gyroscale turbulence
13 Trapped-electron turbulence
14 Turbulence and test particles
15 Current driven MHD instabilities
16 Gyrokinetic gauge transform for large scales
17 Lie-Poisson bracket for gyrokinetics

Ever since the first observations of turbulent fluctuations in laboratory plasma experiments in the years around 1980, turbulence in magnetised plasmas has been a subject of vigorous interest in the field of plasma physics and magnetic confinement. This work fills a significant gap in the set of available references for research in the field, and serves as part of the wider literature helpful in related fields such as geophysical fluid dynamics or astrophysics, in which background rotation is mathematically similar to a background magnetic field in a plasma.

The second of a two-volume set, this book begins with a review of the concepts behind magnetised plasma turbulence as covered in Volume One. After covering the effects of temperature dynamics, especially heat flux inertia, the rest of the first half reviews classical field theory in the necessary language, then builds the gyrokinetic and gyrofluid theory in a systematic and self-consistent manner, with special emphasis on energetic consistency. Gyrofluid turbulence in various flavours in a magnetised plasma is then covered, with control cases and energetic analysis. Familiar magnetohydrodynamic instabilities are reproduced in gyrofluid language, and then turbulence in a flow layer, current channel, pressure layer, or all three, is covered. A reprise of the theory in terms of a gauge transform with functional Lie-Poisson bracket structure closes the volume.

Bruce Scott is a research plasma physicist having graduated with a Doctorate from the University of Maryland in 1985, and with the German Habilitation from the Heinrich-Heine-Universität Düsseldorf in 2001. He is a Fellow of the American Physical Society with membership since 1979. He has several tens of first author papers in peer-reviewed journals in the field of theoretical plasma physics.