301 research outputs found
plasma turbulence in magnetic fields
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Fluctuations and control in the Vlasov-Poisson equation
In this paper we study the fluctuation spectrum of a linearized
Vlasov-Poisson equation in the presence of a small external electric field.
Conditions for the control of the linear fluctuations by an external electric
field are established.Comment: 8 pages late
Plasma transport in stochastic magnetic fields. II. Principles and problems of test electron transport
A model stochastic differential equation is considered which describes guiding center electron motion in a statistically specified spectrum of turbulent magnetic fluctuations. The fluctuation intensity is assumed to satisfy the Chirikov criterion (resonance overlap) for onset of stochasticity. In this limit typical lines diffuse and are adequately described by a quasilinear diffusion coefficient D/sub m/. However, quasilinear theory does not describe an important mechanism for loss of particle correlations: particles collisionally diffuse from one line to an adjacent one which diverges rapidly from the first, carrying the particles away. The scale length L/sub K/ for line divergence is related to the inverse of the Kolmogorov-Sinai entropy. An attempt is made to determine L/sub K/ from a simplified Eulerian vertex renormalization. The exponentiation length which emerges is L/sub K/ approximately L/sub s/(anti k/sup 2//sub theta/D''/sub m/L/sub s/)/sup -1/3/, where L/sub s/ is the shear length, k bar/sub theta/ is a typical azimuthal wavenumber, and D''/sub m/ is of order D/sub m/. In a particular limit of weak shear, the particle diffusion coefficient can then be estimated as D approximately DELTA r/sup 2//tau/sub c/, where ..delta..r/sup 2/ approximately D/sub m/z(tau/sub c/), z(tau) is the distance traveled along the lines in time tau, and for static fluctuations tau/sub c/ approximately tau(L/sub delta/), where L/sub delta/ is L/sub K/ multiplied by a logarithmic factor involving the perpendicular collisional diffusion coefficient
Statistical properties of an ensemble of vortices interacting with a turbulent field
We develop an analytical formalism to determine the statistical properties of
a system consisting of an ensemble of vortices with random position in plane
interacting with a turbulent field. We calculate the generating functional by
path-integral methods. The function space is the statistical ensemble composed
of two parts, the first one representing the vortices influenced by the
turbulence and the second one the turbulent field scattered by the randomly
placed vortices.Comment: Third version; Important corrections in the normalization for the gas
of vortices, et
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