Nonlinear gyrokinetic theory for finite-beta plasmas
- 1 July 1988
- journal article
- Published by AIP Publishing in Physics of Fluids
- Vol. 31 (7) , 1940-1948
- https://doi.org/10.1063/1.866641
Abstract
A self‐consistent and energy‐conserving set of nonlinear gyrokinetic equations, consisting of the averaged Vlasov and Maxwell’s equations for finite‐beta plasmas, is derived. The method utilized in the present investigation is based on the Hamiltonian formalism and Lie transformation. The resulting formulation is valid for arbitrary values of k⊥ρi and, therefore, is most suitable for studying linear and nonlinear evolution of microinstabilities in tokamak plasmas as well as other areas of plasma physics where the finite Larmor radius effects are important. Because the underlying Hamiltonian structure is preserved in the present formalism, these equations are directly applicable to numerical studies based on the existing gyrokinetic particle simulation techniques.Keywords
This publication has 24 references indexed in Scilit:
- Gyrokinetic particle simulation of ion temperature gradient drift instabilitiesPhysics of Fluids, 1988
- Gyrokinetic particle simulation modelJournal of Computational Physics, 1987
- Collisionless electron temperature gradient instabilityPhysics of Fluids, 1987
- Nonlinear evolution of drift instabilities in the presence of collisionsPhysics of Fluids, 1987
- Semicollisional drift-tearing modes in toroidal plasmasPhysics of Fluids, 1986
- Measurements of microturbulence in tokamaks and comparisons with theories of turbulence and anomalous transportNuclear Fusion, 1985
- Low frequency gyrokinetics in general plasma equilibrium in a hamiltonian formulationPhysics Letters A, 1985
- Noncanonical Hamiltonian mechanics and its application to magnetic field line flowAnnals of Physics, 1983
- Microinstability theory in tokamaksNuclear Fusion, 1978
- Particle-Code Models in the Nonradiative LimitPublished by Elsevier ,1976