English

Local-Density Driven Clustered Star Formation

Astrophysics of Galaxies 2015-06-12 v1

Abstract

A positive power-law trend between the local surface densities of molecular gas, Σgas\Sigma_{gas}, and young stellar objects, Σ\Sigma_{\star}, in molecular clouds of the Solar Neighbourhood has been identified by Gutermuth et al. How it relates to the properties of embedded clusters, in particular to the recently established radius-density relation, has so far not been investigated. In this paper, we model the development of the stellar component of molecular clumps as a function of time and initial local volume density so as to provide a coherent framework able to explain both the molecular-cloud and embedded-cluster relations quoted above. To do so, we associate the observed volume density gradient of molecular clumps to a density-dependent free-fall time. The molecular clump star formation history is obtained by applying a constant SFE per free-fall time, \eff\eff. For volume density profiles typical of observed molecular clumps (i.e. power-law slope 1.7\simeq -1.7), our model gives a star-gas surface-density relation ΣΣgas2\Sigma_{\star} \propto \Sigma_{gas}^2, in very good agreement with the Gutermuth et al relation. Taking the case of a molecular clump of mass M0104MsunM_0 \simeq 10^4 Msun and radius R6pcR \simeq 6 pc experiencing star formation during 2 Myr, we derive what SFE per free-fall time matches best the normalizations of the observed and predicted (Σ\Sigma_{\star}, Σgas\Sigma_{gas}) relations. We find \eff0.1\eff \simeq 0.1. We show that the observed growth of embedded clusters, embodied by their radius-density relation, corresponds to a surface density threshold being applied to developing star-forming regions. The consequences of our model in terms of cluster survivability after residual star-forming gas expulsion are that due to the locally high SFE in the inner part of star-forming regions, global SFE as low as 10% can lead to the formation of bound gas-free star clusters.

Keywords

Cite

@article{arxiv.1211.1383,
  title  = {Local-Density Driven Clustered Star Formation},
  author = {Genevieve Parmentier and Susanne Pfalzner},
  journal= {arXiv preprint arXiv:1211.1383},
  year   = {2015}
}

Comments

16 pages, 15 figures, Astronomy & Astrophysics, in press

R2 v1 2026-06-21T22:33:59.387Z