English

Collapse in Self-gravitating Turbulent Fluids

Astrophysics of Galaxies 2016-11-01 v2 Solar and Stellar Astrophysics

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 rdr_d, and the radius rr_* 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, ρ(r,t)ρ(r)\rho(r,t ) \rightarrow \rho(r), for rd<r<rr_d<r<r_*; 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 vTrpv_T \sim r^p with p0.5p \sim 0.5, in agreement with Larson's size-linewidth relation. In the vicinity of massive star forming regions we find p0.20.3 p \sim 0.2-0.3, as seen in observations. For r<rr<r_*, vTv_T increases inward, with p=1/2p=-1/2. Finally, we find that the total stellar mass M(t)t2M_*(t)\sim t^2 in line with previous numerical and analytic work that suggests a nonlinear rate of star formation.

Keywords

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

R2 v1 2026-06-22T11:00:38.014Z