73,300 research outputs found
Velocity statistics from spectral line data: effects of density-velocity correlations, magnetic field, and shear
In a previous work Lazarian and Pogosyan suggested a technique to extract
velocity and density statistics, of interstellar turbulence, by means of
analysing statistics of spectral line data cubes. In this paper we test that
technique, by studying the effect of correlation between velocity and density
fields, providing a systematic analysis of the uncertainties arising from the
numerics, and exploring the effect of a linear shear. We make use of both
compressible MHD simulations and synthetic data to emulate spectroscopic
observations and test the technique. With the same synthetic spectroscopic
data, we also studied anisotropies of the two point statistics and related
those anisotropies with the magnetic field direction. This presents a new
technique for magnetic field studies. The results show that the velocity and
density spectral indices measured are consistent with the analytical
predictions. We identified the dominant source of error with the limited number
of data points along a given line of sight. We decrease this type of noise by
increasing the number of points and by introducing Gaussian smoothing. We argue
that in real observations the number of emitting elements is essentially
infinite and that source of noise vanishes.Comment: 12 pages, 10 figures. Accepted for publication in MNRA
Scaling, Intermittency and Decay of MHD Turbulence
We discuss a few recent developments that are important for understanding of
MHD turbulence.
First, MHD turbulence is not so messy as it is usually believed. In fact, the
notion of strong non-linear coupling of compressible and incompressible motions
along MHD cascade is not tenable. Alfven, slow and fast modes of MHD turbulence
follow their own cascades and exhibit degrees of anisotropy consistent with
theoretical expectations. Second, the fast decay of turbulence is not related
to the compressibility of fluid. Rates of decay of compressible and
incompressible motions are very similar. Third, viscosity by neutrals does not
suppress MHD turbulence in a partially ionized gas. Instead, MHD turbulence
develops magnetic cascade at scales below the scale at which neutrals damp
ordinary hydrodynamic motions. Forth, density statistics does not exhibit the
universality that the velocity and magnetic field do. For instance, at small
Mach numbers the density is anisotropic, but it gets isotropic at high Mach
numbers. Fifth, the intermittency of magnetic field and velocity are different.
Both depend on whether the measurements are done in local system of reference
oriented along the local magnetic field or in the global system of reference
related to the mean magnetic field.Comment: 12 pages, Invited Review, Workshop on Theoretical Plasma Physics,
Trieste, Italy, 5-16 Jul
Magnetic Reconnection and Turbulent Mixing: From ISM to Clusters of Galaxies
Magnetic reconnection, or the ability of the magnetic field lines that are
frozen in plasma to change their topology, is a fundamental problem of
magnetohydrodynamics (MHD). We briefly examine the problem starting with the
well-known Sweet-Parker scheme, discuss effects of tearing modes, anomalous
resistivity and the concept of hyperresistivity. We show that the field
stochasticity by itself provides a way to enable fast reconnection even if, at
the scale of individual turbulent wiggles, the reconnection happens at the slow
Sweet-Parker rate. We show that fast reconnection allows efficient mixing of
magnetic field in the direction perpendicular to the local direction of
magnetic field. While the idea of stochastic reconnection still requires
numerical confirmation, our numerical simulations testify that mixing motions
perpendicular to the local magnetic field are up to high degree hydrodynamical.
This suggests that the turbulent heat transport should be similar to that in
non-magnetized turbulent fluid, namely, should have a diffusion coefficient
\sim LV_L, where V_L is the amplitude of the turbulent velocity and L is the
scale of the turbulent motions. We present numerical simulations which support
this conclusion. The application of this idea to thermal conductivity in
clusters of galaxies shows that this mechanism may dominate the diffusion of
heat and may be efficient enough to prevent cooling flow formation.Comment: 12 pages, 2 figures, invited talk at JENAM2002 - The Unsolved
Universe:Challenges for the Future (v2: minor changes
Localizing global hedgehogs on the brane
We investigate the localization of 4D topological global defects on the brane
embedded in 5D. The defects are induced by 5D scalar fields with a
symmetry-breaking potential. Taking an ansatz which separates the scalar field
into the 4D and the extra-D part, we find that the static-hedgehog
configuration is accomplished and the defects are formed only in the
background. In the extra dimension, the localization amplitude
for the 4D defects is high where the warp factor is high.Comment: 17 pages, revte
One-dimensional Excitations in Superfluid He and He-He Mixture Films Adsorbed in Porous Materials
A normal-fluid component varying as T is observed at very low
temperatures in superfluid He and He-He mixture films adsorbed in
alumina powder. The normal fluid appears to arise from thermally excited third
sound that has one-dimensional propagation characteristics. A Landau model of
third sound excitations in an infinite cylindrical pore by Saam and Cole
provides good agreement with the experimental measurements over a wide range of
He and He coverages. However, it is unclear why the powder substrate
can be modeled as having cylindrical pores.Comment: 5 pages, 6 figures, revtex4, to appear in PR
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