Collapse in Self-gravitating Turbulent Fluids
Abstract
Motivated by the nonlinear star formation efficiency found in recent numerical simulations by a number of workers, we perform high-resolution adaptive mesh refinement simulations of star formation in self-gravitating turbulently driven gas. As we follow the collapse of this gas, we find that the character of the flow changes at two radii, the disk radius , and the radius where the enclosed gas mass exceeds the stellar mass. Accretion starts at large scales and works inwards. In line with recent analytical work, we find that the density evolves to a fixed attractor, , for ; mass flows through this structure onto a sporadically gravitationally unstable disk, and from thence onto the star. In the bulk of the simulation box we find that the random motions with , in agreement with Larson's size-linewidth relation. In the vicinity of massive star forming regions we find , as seen in observations. For , increases inward, with . Finally, we find that the total stellar mass in line with previous numerical and analytic work that suggests a nonlinear rate of star formation.
Cite
@article{arxiv.1509.05910,
title = {Collapse in Self-gravitating Turbulent Fluids},
author = {Daniel W. Murray and Philip Chang and Norman W. Murray and John Pittman},
journal= {arXiv preprint arXiv:1509.05910},
year = {2016}
}
Comments
22 pages, 31 figures, Accepted to Monthly Notices of the Royal Astronomical Society