Kinetic Energy Decay Rates of Supersonic and Super-Alfvénic Turbulence in Star-Forming Clouds
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In this paper, the authors present numerical studies of compressible, decaying turbulence, with and without magnetic fields, with initial rms Alfven and Mach numbers ranging up to five, and apply the results to the question of the support of star-forming in terstellar clouds of molecular gas.Abstract:
We present numerical studies of compressible, decaying turbulence, with and without magnetic fields, with initial rms Alfven and Mach numbers ranging up to five, and apply the results to the question of the support of star-forming in- terstellar clouds of molecular gas. We find that, in 1D, magnetized turbulence actually decays faster than unmagnetized turbulence. In all the regimes that we have studied 3D turbulence—super-Alfvenic, supersonic, sub-Alfvenic, and subsonic—the kinetic energy decays as (t t0) � , with 0.85 < � < 1.2. We compared results from two entirely different algorithms in the unmagnetized case, and have performed extensive resolution studies in all cases, reaching resolutions of 256 3 zones or 350,000 particles. We conclude that the observed long lifetimes and supersonic motions in molecular clouds must be due to external driving, as undriven turbulence decays far too fast to explain the observations.read more
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Astrophysical magnetic fields and nonlinear dynamo theory
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Interstellar Turbulence I: Observations and Processes
Bruce G. Elmegreen,John Scalo +1 more
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Control of Star Formation by Supersonic Turbulence
TL;DR: A review of the successes and problems of both the classical dynamical theory and the standard theory of magnetostatic support, from both observational and theoretical perspectives, is given in this article.
References
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Book
Turbulence in fluids
TL;DR: In this article, the transition from transition to Turbulence in fluid mechanics is described as follows: "Basic Fluid Dynamics, Transition to Turbence, Shear Flow Turbulence, Fourier Analysis of Homogeneous Turburbence, Isotropic Turbulences: Phenomenology and Simulations".