WOCS 5379: Detailed Analysis of the Evolution of a Post-Mass-Transfer Blue Straggler

TL;DR

This study models the evolution of a blue straggler binary system in NGC 188, revealing details of its mass transfer history and stellar evolution, and comparing simulations with observations.

Contribution

It provides a detailed MESA-based evolutionary model of a post-mass-transfer blue straggler system, including non-conservative mass transfer effects and orbital evolution.

Findings

Successful reproduction of the blue straggler's properties using initial masses and 22% mass transfer efficiency.

Identification of a short unstable mass transfer phase during system evolution.

Modeled white dwarf mass slightly smaller than observed, indicating areas for further refinement.

Abstract

The blue-straggler binary WOCS 5379 is a member of the old (6-7 Gyr) open cluster NGC 188. WOCS 5379 comprises a blue straggler star with a white dwarf companion in a 120-day eccentric orbit. Combined with the orbital period, this helium white dwarf is evidence of previous mass transfer by a red giant. Detailed models of the system evolution from a progenitor main-sequence binary, including mass transfer, are made using the Modules for Experiments in Stellar Astrophysics (MESA). Both of the progenitor stars are evolved in the simulation. WOCS 5379 is well reproduced with a primary star of initial mass 1.19 $M_{\odot}$, whose core becomes the white dwarf. The secondary star initially is 1.01 $M_{\odot}$. 300 Myr ago, the secondary finished receiving mass from the donor, having moved beyond the NGC 188 turnoff as a 1.20 $M_{\odot}$ blue straggler. The successful model has a mass transfer efficiency of 22\%. This non-conservative mass transfer is key to expanding the orbit fast enough to permit stable mass transfer. Even so, the mass transfer begins with a short unstable phase, during which half of the accreted mass is transferred. With increasing mass, the secondary evolves from a radiative core to a convective core. The final blue straggler interior is remarkably similar to a 2.1 Gyr-old 1.21 $M_{\odot}$ main-sequence star at the same location in the HR diagram. The white dwarf effective temperature is also reproduced, but the modeled white dwarf mass of 0.33 $M_{\odot}$ is smaller than the measured mass of 0.42 $M_{\odot}$.