Non standard s-process in massive rotating stars. Yields of 10-150 M models at Z=10-3

Abstract

Recent studies show that rotation significantly affects the s-process in massive stars. We provide tables of yields for non-rotating and rotating massive stars between 10 and 150 M at Z=10-3 ([Fe/H] =-1.8). Tables for different mass cuts are provided. The complete s-process is followed during the whole evolution with a network of 737 isotopes, from Hydrogen to Polonium. A grid of stellar models with initial masses of 10, 15, 20, 25, 40, 60, 85, 120 and 150 M and with an initial rotation rate of both 0 or 40~\% of the critical velocity was computed. Three extra models were computed in order to investigate the effect of faster rotation (70~\% of the critical velocity) and of a lower 17O(α,γ) reaction rate. At the considered metallicity, rotation has a strong impact on the production of s-elements for initial masses between 20 and 60 M. In this range, the first s-process peak is boosted by 2-3 dex if rotation is included. Above 60 M, s-element yields of rotating and non-rotating models are similar. Increasing the initial rotation from 40~\% to 70~\% of the critical velocity enhances the production of 40 Z 60 elements by 0.5-1 dex. Adopting a reasonably lower 17O(α,γ) rate in the fast rotating model (70~\% of the critical velocity) boosts again the yields of s-elements with 55 Z 82 by about 1 dex. In particular, a modest amount of Pb is produced. Together with s-elements, some light elements (particularly fluorine) are strongly overproduced in rotating models.