Stellar, brown dwarf and multiple star properties from a radiation hydrodynamical simulation of star cluster formation

TL;DR

This study uses advanced radiation hydrodynamical simulations to model star cluster formation, successfully reproducing many observed stellar and brown dwarf properties, highlighting the importance of radiative feedback in star formation.

Contribution

It presents the largest radiation hydrodynamical simulation resolving down to the opacity limit, providing detailed statistical properties of stars and brown dwarfs consistent with observations.

Findings

Simulation reproduces observed stellar mass function.

Radiative feedback reduces brown dwarf overproduction.

Statistical properties of stars match observed distributions.

Abstract

We report the statistical properties of stars, brown dwarfs and multiple systems obtained from the largest radiation hydrodynamical simulation of star cluster formation to date that resolves masses down to the opacity limit for fragmentation (a few Jupiter masses). The initial conditions are identical to those of previous barotropic calculations published by Bate, but this time the calculation is performed using a realistic equation of state and radiation hydrodynamics. The calculation uses sink particles to model 183 stars and brown dwarfs, including 28 binaries and 12 higher-order multiple systems, the properties of which are compared the results from observational surveys. We find that the radiation hydrodynamical/sink particle simulation reproduces many observed stellar properties very well. In particular, whereas using a barotropic equation of state produces more brown dwarfs than stars, the inclusion of radiative feedback results in a stellar mass function and a ratio of brown dwarfs to stars in good agreement with observations of Galactic star-forming regions. In addition, many of the other statistical properties of the stars and brown dwarfs are in reasonable agreement with observations, including multiplicity as a function of primary mass, the frequency of very-low-mass binaries, and general trends for the mass ratio and separation distributions of binaries. We also examine the velocity dispersion of the stars, the distributions of disc truncation radii due to dynamical interactions, and coplanarity of orbits and sink particle spins in multiple systems. Overall, the calculation produces a cluster of stars whose statistical properties are difficult to distinguish from observed systems, implying that gravity, hydrodynamics, and radiative feedback are the primary ingredients for determining the origin of the statistical properties of low-mass stars.