Time Varying Dynamical Star Formation Rate
Abstract
We present numerical evidence of dynamic star formation in which the accreted stellar mass grows superlinearly with time, roughly as . We perform simulations of star formation in self-gravitating hydrodynamic and magneto-hydrodynamic turbulence that is continuously driven. By turning the self-gravity of the gas in the simulations on or off, we demonstrate that self-gravity is the dominant physical effect setting the mass accretion rate at early times before feedback effects take over, contrary to theories of turbulence-regulated star formation. We find that gravitational collapse steepens the density profile around stars, generating the power-law tail on what is otherwise a lognormal density probability distribution function. Furthermore, we find turbulent velocity profiles to flatten inside collapsing regions, altering the size-linewidth relation. This local flattening reflects enhancements of turbulent velocity on small scales, as verified by changes to the velocity power spectra. Our results indicate that gas self-gravity dynamically alters both density and velocity structures in clouds, giving rise to a time-varying star formation rate. We find that a substantial fraction of the gas that forms stars arrives via low density flows, as opposed to accreting through high density filaments.
Cite
@article{arxiv.1406.4148,
title = {Time Varying Dynamical Star Formation Rate},
author = {Eve J. Lee and Philip Chang and Norman Murray},
journal= {arXiv preprint arXiv:1406.4148},
year = {2015}
}
Comments
14 pages, 14 figures, to appear in ApJ. Added purely compressive turbulence driving for FLASH runs