Physics of solar system plasmas
Phillips and Jonathan E. Menard Waves in a cold magnetized plasma; resonances and cutoffs; energy transport; normal modes for a hot plasma; Landau and cyclotron damping; velocity-space instabilities; quasilinear diffusion; propagation through an inhomogeneous plasma; mode conversion drift waves; absolute and convective instabilities; effects of weak collisions; and applications to plasma confinement, radio frequency plasma heating, and magnetospheric propagation.
Hammett Fluctuations and transport in plasma, origins of irreversibility, Fokker-Planck theory, statistical hierarchies, kinetic equations, limiting forms of the Coulomb collision operator, test-particle calculations, radiation, fluctuation-dissipation theorem, transport coefficients in magnetized plasma, and Onsager relations. Applications to current problems in plasma research. Efthimion, Richard P.
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Majeski, and Michael C. Zarnstorff This course gives an introduction to experimental plasma physics, with an emphasis on high-temperature plasmas for fusion.
Requirements for fusion plasmas: confinement, beta, power and particle exhaust. Tokamak fusion reactors. Status of experimental understanding: what we know and how we know it.
White Magnetic coordinates, tokamak equilibria, Hamiltonian guiding center formalism, transport in the presence of ripple and MHD modes, nonlinear MHD and resistive modes, and the kinetic destabilization of MHD modes. White Local analysis of solutions to linear and nonlinear differential and difference equations, asymptotic methods, asymptotic analysis of integrals, perturbation theory, summation methods, boundary layer theory, WKB theory, and multiple-scale theory.
Davidson Fall Nathaniel J. Fisch and Allan Reiman Spring The purpose of the course is to acquaint students with current developments in high-temperature plasma physics and fusion research. Topics are drawn from current literature and may encompass advances in experimental and theoretical studies of laboratory and naturally-occurring high-temperature plasmas, including stability and transport, nonlinear dynamics and turbulence, magnetic reconnection, self-heating of "burning" plasmas, and innovative concepts for advanced fusion systems.
Topics may also cover advances in plasma applications, including laser-plasma interactions, nonnuetral plasms, high-intensity accelerators, plasma propulsion, plasma processing, and coherent electromagnetic wave generation. The Graduate Seminar in Plasma Physics is currently organized each semester around special topics in experimental and theoretical plasma physics, with recent topics including nonneutral plasmas and advanced accelerators Spring Semester, , and magnetic reconnection in laboratory and space plasmas Fall Semester, Following one or two introductory lectures by the faculty, each graduate student gives one of the weekly seminars based on a particular published article taken from a small repository of topical papers prepared by the faculty.
Krommes A comprehensive introduction to the theory of turbulence and transport in plasma: transition to turbulence, fundamental mechanisms for turbulence, stochasticity; experimental observations; fundamental equations, especially nonlinear gyrokinetics; computer simulations; linear and nonlinear wave-particle and wave-wave interactions; statistical closures, including the direct-interaction approximation; variational methods. This paper reviews the conditions for, and the structure of, the thermal equilibrium states.
Both theory and experiment are discussed, but the emphasis is decidedly on theory.
It is a huge advantage to be able to use thermal equilibrium statistical mechanics to describe the plasma state. Such a description is easily obtained and complete, including for example the details of the plasma shape and microscopic order. Pure electron and pure ion plasmas are routinely confined for hours and even days, and thermal equilibrium states are observed.
These plasmas can be cooled to the cryogenic temperature range, where liquid and crystal-like states are realized.
- Catalog Record: An introduction to the physics of nonneutral | HathiTrust Digital Library.
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The authors discuss the structure of the correlated states separately for three plasma sizes: large plasmas, in which the free energy is dominated by the bulk plasma; mesoscale plasmas, in which the free energy is strongly influenced by the surface; and Coulomb clusters, in which the number of particles is so small that the canonical ensemble is not a good approximation for the microcanonical ensemble.
All three cases have been studied through numerical simulations, analytic theory, and experiment. In addition to describing the structure of the thermal equilibrium states, the authors develop a thermodynamic theory of the trapped plasma system. Thermodynamic inequalities and Maxwell relations provide useful bounds on and general relationships between partial derivatives of the various thermodynamic variables. Daniel H. Dubin and T. Trapped nonneutral plasmas, liquids, and crystals the thermal equilibrium states Daniel H.
plasma frequency in non-neutral plasma - Physics Stack Exchange
Abstract Authors References. Abstract Plasmas consisting exclusively of particles with a single sign of charge e. Issue Vol. Authorization Required. Log In.