On the Origin of Neutron-capture Elements in r-I and r-II Stars: A Differential-abundance Analysis

Abstract

We present a strictly line-by-line differential analysis of a moderately r-process-enhanced star (r-I: HD~107752) with respect to a strongly r-process-enhanced star (r-II: CS~31082-0001) to investigate the possible common origin of their heavy-element nucleosynthesis with high-precision abundances. This study employs ESO data archive high-resolution and high signal-to-noise spectra taken with the UVES (VLT) spectrograph. Considering only the lines in common in both spectra, we estimate differential abundances of 16 light/Fe-peak elements and 15 neutron-capture elements. Abundances of O, Al, Pr, Gd, Dy, Ho, Er, and detection of Tm in HD~107752 are presented for the first time. We found three distinct features in the differential-abundance pattern. Nearly equal abundances of light elements up to Zn are present for both the stars, indicating a common origin for these elements; in addition to no noticable odd-even differential pattern. In the case of neutron-capture elements, the r-I star exhibits mildly depleted light r-process elements and more depleted heavier r-process elements relative to r-II star. We also show that among r-I and r-II stars, the ratio of lighter-to-heavier r-process elements (e.g. [(Sr,Y,Zr)/Eu]) exhibits a decreasing trend with respect to the overall r-process enhancement, forming a continuous sequence from r-I and r-II stars. Finally, we discuss the necessity of multiple sites for the formation of r-I stars.