http://arxiv.org/abs/1502.02670
We propose a novel scenario for the formation of Globular Clusters (GCs) based on the merger of two or more atomic cooling halos at high-redshift (z>6). The model naturally fulfills several key observational constraints on GCs that have emerged in the last decade. Specifically, absolute and relative ages, widespread presence of multiple stellar populations, spatial distribution around host galaxies, and correlations between galactocentric radius and metallicity. In our framework, the oldest globular clusters form the first generation stars as an intense burst in the center of a minihalo that grows above the threshold for hydrogen cooling (halo mass M_h~1e8 Msun) and undergoes a major merger within the cooling timescale (~150 Myr). Subsequent minor mergers and sustained gas infall bring new supply of pristine gas at the halo center, diluting AGB ejecta, and triggering additional bursts of star formation which form multiple generation of stars in the majority of the clusters. The DM halo around the GC is then stripped during assembly of the host galaxy halo. Our modeling is based on the merging history of dark-matter halos, and thus has no free adjustable parameters within the concordance LCDM cosmology. As a first application, based on a high-resolution cosmological simulation, we make quantitative predictions for the age distribution of the old GC population (Age=13.0+/-0.2 Gyr). We suggest that a similar merging mechanism is responsible for forming the sequence of younger and progressively metal richer clusters, through subhalo-subhalo merging in the later stages of massive halo assembly.
M. Trenti, P. Padoan and R. Jimenez
Wed, 11 Feb 15
14/72
Comments: 12 pages, submitted to ApJ, comments welcome