The Life and Times of Star-Forming Cores: an Analysis of Dense Gas in the STARFORGE Simulations

TL;DR

This study uses STARFORGE simulations to analyze dense gas cores in molecular clouds, revealing core lifetimes, evolution patterns, and the influence of turbulence, gravity, and feedback on star formation processes.

Contribution

It provides a detailed analysis of core evolution from birth to dispersal, highlighting the roles of turbulence, gravity, and feedback in star formation.

Findings

Most cores disperse before forming stars.

Protostellar phase lasts about 0.1 Myr.

Core properties cluster into distinct groups.

Abstract

Dense gas in molecular clouds is an important signature of ongoing and future star formation. We identify and track dense cores in the STARFORGE simulations, following the core evolution from birth through dispersal by stellar feedback for typical Milky Way cloud conditions. Only $\sim$8% of cores host protostars, and most disperse before forming stars. The median starless and protostellar core lifetimes are $\sim 0.5-0.6$ Myr and $\sim0.8-1.1$ Myr, respectively, where the protostellar phase lasts $\sim 0.1^{+0.1}_{-0.05}$ Myr. While core evolution is stochastic, we find that virial ratios and linewidths decline in prestellar cores, coincident with turbulent decay. Collapse occurs over $\sim 0.1$ Myr, once the central density exceeds $\gtrsim 10^6$cm$^{-3}$. Starless cores, only, follow linewidth-size and mass-size relations, $\sigma \propto R^{0.3}$ and $M \propto R^1$. The core median mass, radius, and velocity dispersion scale weakly with the cloud magnetic field strength. We cluster the core properties and find that protostellar cores have $>80$% likelihood of belonging to three particular groups that are characterized by high central densities, compact radii, and lower virial parameters. Overall, core evolution appears to be universally set by the interplay of gravity and magnetized turbulence, while stellar feedback dictates protostellar core properties and sets the protostellar phase lifetime.