Volume Density Thresholds for Overall Star Formation imply Mass-Size Thresholds for Massive Star Formation

Abstract

We aim at understanding the massive star formation (MSF) limit m(r) = 870 M (r/pc)1.33 in the mass-size space of molecular structures recently proposed by Kauffmann & Pillai (2010). As a first step, we build on the hypothesis of a volume density threshold for overall star formation and the model of Parmentier (2011) to establish the mass-radius relations of molecular clumps containing given masses of star-forming gas. Specifically, we relate the mass mclump, radius rclump and density profile slope -p of molecular clumps which contain a mass mth of gas denser than a volume density threshold th. In a second step, we use the relation between the mass of embedded-clusters and the mass of their most-massive star to estimate the minimum mass of star-forming gas needed to form a 10\,M star. Assuming a star formation efficiency of SFE 0.30, this gives mth,crit 150 M. In a third step, we demonstrate that, for sensible choices of the clump density index (p 1.7) and of the cluster formation density threshold (nth 104\,cm-3), the line of constant mth,crit 150 M in the mass-radius space of molecular structures equates with the MSF limit for spatial scales larger than 0.3\,pc. Hence, the observationally inferred MSF limit of Kauffmann & Pillai is consistent with a threshold in star-forming gas mass beyond which the star-forming gas reservoir is large enough to allow the formation of massive stars. For radii smaller than 0.3\,pc, the MSF limit is shown to be consistent with the formation of a 10\,M star out of its individual pre-stellar core of density threshold nth 105\,cm-3. The inferred density thresholds for the formation of star clusters and individual stars within star clusters match those previously suggested in the literature.