English

Cooling, Gravity and Geometry: Flow-driven Massive Core Formation

Astrophysics 2009-11-13 v1

Abstract

We study numerically the formation of molecular clouds in large-scale colliding flows including self-gravity. The models emphasize the competition between the effects of gravity on global and local scales in an isolated cloud. Global gravity builds up large-scale filaments, while local gravity -- triggered by a combination of strong thermal and dynamical instabilities -- causes cores to form. The dynamical instabilities give rise to a local focusing of the colliding flows, facilitating the rapid formation of massive protostellar cores of a few 100 M_\odot. The forming clouds do not reach an equilibrium state, though the motions within the clouds appear comparable to ``virial''. The self-similar core mass distributions derived from models with and without self-gravity indicate that the core mass distribution is set very early on during the cloud formation process, predominantly by a combination of thermal and dynamical instabilities rather than by self-gravity.

Keywords

Cite

@article{arxiv.0709.2451,
  title  = {Cooling, Gravity and Geometry: Flow-driven Massive Core Formation},
  author = {Fabian Heitsch and Lee Hartmann and Adrianne D. Slyz and Julien E. G. Devriendt and Andreas Burkert},
  journal= {arXiv preprint arXiv:0709.2451},
  year   = {2009}
}

Comments

13 pages, 12 figures, accepted by ApJ

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