Quantum Plasmadynamics, 2013
Magnetized Plasmas
Lecture Notes in Physics Series, Vol. 854

Quantum Plasmadynamics is a synthesis of the kinetic theory of plasmas and quantum electrodynamics (QED). In this volume, the approach applied to unmagnetized plasmas in volume 1 is generalized to magnetized plasmas. First, a covariant version of nonquantum kinetic theory is formulated for single-particle (emission and scattering)  processes and the collective-medium response. The relativistic quantum treatment is based on solutions of Dirac's equation for an electron in a magnetostatic field, and single-particle processes are treated using a magnetized version of QED. The response of an electron gas is derived by generalizing the derivation of the response of the magnetized vacuum.

Preface.- Chapter 1: Covariant Fluid Models for Magnetized Plasmas.- Chapter 2: Response Tensors for Magnetized Plasmas.- Chapter 3: Waves in Magnetized Plasmas.- Chapter 4: Gyromagnetic Processes.- Chapter 5: Magnetized Dirac Electron.- Chapter 6: Quantum Theory of Gyromagnetic Processes.- Chapter 7: Second Order Gyromagnetic Processes.- Chapter 8: Magnetized Vacuum.- Chapter 9: Response of Magnetized Electron Gas.- Appendix A: Special Functions.- Index.

Following completion of his doctoral thesis in theoretical particle physics at Oxford University in 1965, Don Melrose changed his research interests to plasma astrophysics. In 1969, after post-doctoral appointments in the UK and the USA, he returned to Australia to the Australian National University. He eventually left to take his current appointment as Professor of Physics (Theoretical) at the University of Sydney in 1979. He made important contributions to the theory of coherent emission processes in astrophysics: plasma emission in solar radio bursts, electron cyclotron maser emission and pulsar radio emission. His current interests include pulsars, quantum plasmas and solar flares.

Presents an authoritative and comprehensive formulation of plasma kinetic theory, including all relativistic and quantum effects, plus the response of the vacuum

Suitable both as a graduate level text and a reference source for researchers

Features the treatment of the collective response of an electron gas based on exact solutions of Dirac's equation in the presence of a magnetic field of arbitrary strength