http://arxiv.org/abs/1809.05539
We find that around half of highly r-process enhanced (r-II) metal-poor halo stars may have originated in early ultra-faint dwarf galaxies that merged into the Milky Way during its formation. If there is such a connection, the r-II stars we observe today could play a key role in understanding the smallest building blocks of the Milky Way. To conduct this initial investigation, we use high-resolution cosmological simulations of Milky-Way-mass galaxies (the Caterpillar suite) in combination with a simple, empirically motivated treatment of r-process enrichment. We determine the fraction of metal-poor halo stars that could have formed from highly r-process enhanced gas in now-destroyed ultra-faint dwarfs, the simulated r-II fraction, and compare this to the observed r-II fraction. We find that the simulated fraction (f_{r-II,sim} ~ 1-2%) can account for around half of the observed fraction (f_{r-II,obs} ~ 2-4%) when taken at face value. Due to publishing bias, though, the observed fraction probably overrepresents the number of r-II stars, meaning f_{r-II,sim} likely accounts for more than half of the true f_{r-II,obs}. Further considering some parameter variation and scatter between simulations, the simulated fraction can account for around ~20-80% of the observed fraction.
K. Brauer, A. Ji, A. Frebel, et. al.
Tue, 18 Sep 18
69/70
Comments: 15 pages, 6 figures, 2 tables, submitted to ApJ