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Title:
The Small-Scale Structure of Magnetohydrodynamic Turbulence with Large Magnetic Prandtl Numbers
Authors:
Schekochihin, Alexander A.; Maron, Jason L.; Cowley, Steven C.; McWilliams, James C.
Affiliation:
AA(Plasma Physics Group, Imperial College, Blackett Laboratory, Prince Consort Road, London SW7 2BW, England ), AB(Plasma Physics Group, Imperial College, Blackett Laboratory, Prince Consort Road, London SW7 2BW, England ), AC(Plasma Physics Group, Imperial College, Blackett Laboratory, Prince Consort Road, London SW7 2BW, England ), AD(Department of Atmospheric Sciences, UCLA, Los Angeles, CA 90095-1565 )
Publication:
The Astrophysical Journal, Volume 576, Issue 2, pp. 806-813. (ApJ Homepage)
Publication Date:
09/2002
Origin:
UCP
Astronomy Keywords:
Galaxies: Magnetic Fields, ISM: Magnetic Fields, Magnetic Fields, Magnetohydrodynamics: MHD, Plasmas, Turbulence
DOI:
10.1086/341814
Bibliographic Code:
2002ApJ...576..806S

Abstract

We study the intermittency and field-line structure of the MHD turbulence in plasmas with very large magnetic Prandtl numbers. In this regime, which is realized in the interstellar medium, some accretion disks, protogalaxies, galaxy-cluster gas, the early universe, etc., magnetic fluctuations can be excited at scales below the viscous cutoff. The salient feature of the resulting small-scale magnetic turbulence is the folded structure of the fields. It is characterized by very rapid transverse spatial oscillation of the field direction, while the field lines remain largely unbent up to the scale of the flow. Quantitatively, the fluctuation level and the field-line geometry can be studied in terms of the statistics of the field strength and of the field-line curvature. In the kinematic limit, the distribution of the field strength is an expanding lognormal, while that of the field-line curvature K is stationary and has a power tail ~K-13/7. The field strength and curvature are anticorrelated, i.e., the growing fields are mostly flat, while the sharply curved fields remain relatively weak. The field, therefore, settles into a reduced-tension state. Numerical simulations demonstrate three essential features of the nonlinear regime. First, the total magnetic energy is equal to the total kinetic energy. Second, the intermittency is partially suppressed compared to the kinematic case, as the fields become more volume-filling and their distribution develops an exponential tail. Third, the folding structure of the field is unchanged from the kinematic case: the anticorrelation between the field strength and the curvature persists, and the distribution of the latter retains the same power tail. We propose a model of back-reaction based on the folding picture that reproduces all of the above numerical results.
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