When Feedback Fails: The Scaling and Saturation of Star Formation Efficiency

Abstract

We present a suite of 3D multi-physics MHD simulations following star formation in isolated turbulent molecular gas disks ranging from 5 to 500 parsecs in radius. These simulations are designed to survey the range of surface densities between those typical of Milky Way GMCs ( 102 M\,pc-2) and extreme ULIRG environments ( 102 M\,pc-2) so as to map out the scaling of the cloud-scale star formation efficiency (SFE) between these two regimes. The simulations include prescriptions for supernova, stellar wind, and radiative feedback, which we find to be essential in determining both the instantaneous per-freefall (εff) and integrated (εint) star formation efficiencies. In all simulations, the gas disks form stars until a critical stellar surface density has been reached and the remaining gas is blown out by stellar feedback. We find that surface density is a good predictor of εint, as suggested by analytic force balance arguments from previous works. SFE eventually saturates to 1 at high surface density. We also find a proportional relationship between εff and εint, implying that star formation is feedback-moderated even over very short time-scales in isolated clouds. These results have implications for star formation in galactic disks, the nature and fate of nuclear starbursts, and the formation of bound star clusters. The scaling of εff with surface density is not consistent with the notion that εff is always 1\% on the scale of GMCs, but our predictions recover the 1\% value for GMC parameters similar to those found in sprial galaxies, including our own.