s-process enirchment and the origin of barium in ultrafaint dwarf galaxies

Recent spectroscopic observations of ultrafaint dwarf galaxies (UFDs) revealed that the small, old galaxies contain a substantial amount of neutron-capture elements such as Barium (Ba), Strontium (Sr) and Europium (Eu). We use cosmological simulations to study the production of Ba in UFDs. Ba is produced by both {\it r-} and {\it s-}processes, and one can infer the contribution of the {\it r-}process from the characteristic {\it r-}process abundance pattern, whereas the {\it s-}process contribution remains largely unknown. We show that the current {\it s-}process yield from asymptotic giant branch (AGB) stars is not sufficient to explain the Ba abundances observed in UFDs. Ba production would need to be efficient from the beginning of star formation in the galaxies. The discrepancy of nearly $1$ dex is not reconciled even if we consider {\it s-}process in super-AGB stars. We consider a possible resolution by assuming additional Ba production with short delay time. Considering the diversity of Ba abundances among different UFDs, a rare and prolific source is favoured. Fast-rotating massive stars could be such rare and prolific sources, and they can account for the observed abundance if $\sim 3\times 10^{-10}$ Msun of Ba is produced per 1 Msun formed stars. We also explore another resolution by modifying the stellar initial mass function (IMF) in UFDs, and find a particular IMF model that reproduces the observed level of Ba-enrichment. We argue that future observations that determine or tightly constrain the Eu abundance are crucial to identify the origin of Ba in UFDs.