Massive Thorne-Zytkow objects: structure and nucleosynthesis

Abstract

The structure of stars with massive envelopes (M_env ≳ 14 M_⊙) and degenerate neutron cores is discussed. In such stars, most of the luminosity arises from thermonuclear reactions taking place at the base of the convective envelope. The proton-rich material in this region, continuously linked to the outer regions by convection, provides an ideal site for the rp-process. In addition, material may repeatedly pass through the burning zone, with large intervals between each passage, allowing the formation of heavy nuclei up to A ~ 150. Evolutionary calculations are presented of the structure of such stars and of the nucleosynthesis in their envelopes. A lower mass limit of ~ 14 M_⊙ is found for stars of this type. Assuming a lifetime of ≳ 10⁵ yr, a significant fraction, ~ 5 per cent, of the envelope mass is converted to metals beyond iron, and, for a restricted range of masses (depending on the somewhat uncertain details of envelope convection), some of the p-nuclei are produced in relative abundances reminiscent of those found for the Solar system. The abundance peak at molybdenum is, however, not reproduced. If Thorne–Żytkow objects are a later stage in the evolution of massive X-ray binaries then, even if only a small fraction of Thorne–Żytkow objects produce the more massive p-nuclei, the progenitor population is sufficiently large to account for the observed abundances of some of these nuclei.