Turbulent mixing of r-process elements in the Milky Way

Abstract

We study turbulent gas diffusion affects on r-process abundances in Milky Way stars, by a combination of an analytical approach and a Monte Carlo simulation. Higher r-process event rates and faster diffusion, lead to more efficient mixing corresponding to a reduced scatter of r-process abundances and causing r-process enriched stars to start appearing at lower metallicities. We use three independent observations to constrain the model parameters: (i) the scatter of radioactively stable r-process element abundances, (ii) the largest r-process enrichment values observed in any solar neighborhood stars and (iii) the isotope abundance ratios of different radioactive r-process elements (244Pu/238U and 247Cm/238U) at the early solar system as compared to their formation. Our results indicate that the Galactic r-process rate and the diffusion coefficient are respectively r<4× 10-5 yr-1, D>0.1 kpc2Gyr-1 (r<4× 10-6 yr-1, D>0.5 kpc2Gyr-1 for collapsars or similarly prolific r-process sources) with allowed values satisfying an approximate anti-correlation such that D≈ r-2/3, implying that the time between two r-process events that enrich the same location in the Galaxy, is τ mix≈ 100-200 Myr. This suggests that a fraction of 0.8 ( 0.5) of the observed 247Cm (244Pu) abundance is dominated by one r-process event in the early solar system. Radioactively stable element abundances are dominated by contributions from 10 different events in the early solar system. For metal poor stars (with [Fe/H] -2), their r-process abundances are dominated by either a single or several events, depending on the star formation history.