The Turbulence Spectrum of Molecular Clouds in the Galactic Ring Survey: A Density-dependent Principal Component Analysis Calibration

Turbulence plays a major role in the formation and evolution of molecular clouds. Observationally, turbulent velocities are convolved with the density of an observed region. To correct for this convolution, we investigate the relation between the turbulence spectrum of model clouds, and the statisti...

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Veröffentlicht in:The Astrophysical journal 2011-10, Vol.740 (2), p.120-jQuery1323902639348='48'
Hauptverfasser: Roman-Duval, Julia, Federrath, Christoph, Brunt, Christopher, Heyer, Mark, Jackson, James, Klessen, Ralf S
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Sprache:eng
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Zusammenfassung:Turbulence plays a major role in the formation and evolution of molecular clouds. Observationally, turbulent velocities are convolved with the density of an observed region. To correct for this convolution, we investigate the relation between the turbulence spectrum of model clouds, and the statistics of their synthetic observations obtained from principal component analysis (PCA). We apply PCA to spectral maps generated from simulated density and velocity fields, obtained from hydrodynamic simulations of supersonic turbulence, and from fractional Brownian motion (fBm) fields with varying velocity, density spectra, and density dispersion. We examine the dependence of the slope of the PCA pseudo-structure function, Delta *aPCA, on intermittency, on the turbulence velocity ( Delta *b v ) and density ( Delta *b n ) spectral indexes, and on density dispersion. We find that PCA is insensitive to Delta *b n and to the log-density dispersion Delta *s s , provided Delta *s s 2, Delta *aPCA increases with Delta *s s due to the intermittent sampling of the velocity field by the density field. The PCA calibration also depends on intermittency. We derive a PCA calibration based on fBm structures with Delta *s s
ISSN:0004-637X
1538-4357
DOI:10.1088/0004-637X/740/2/120