The thermal equilibrium mass loss model and its applications in binary evolution

TL;DR

This paper develops a thermal equilibrium mass loss model to determine critical mass ratios in binary star systems, enhancing understanding of mass transfer stability and its role in binary evolution outcomes.

Contribution

It introduces a novel thermal equilibrium mass loss model and derives critical mass ratios for different mass transfer regimes in binary star evolution.

Findings

Critical mass ratios for thermal and unstable mass transfer are derived.

Unstable mass transfer via L2 can lead to common envelope formation.

Mass transfer channels vary with donor mass and evolutionary stage.

Abstract

Binary evolution is indispensable in stellar evolution to understand the formation and evolution of most peculiar and energetic objects, such as binary compact objects, Type Ia supernovae, X-ray binaries, cataclysmic variables, blue stragglers, hot subdwarfs, and central binaries in planetary nebulae. Mass transfer in binary stars can change the evolutionary path and fate of the corresponding objects relative to what is expected from single stellar evolution. What is the critical mass ratio at which unstable mass transfer occurs is an unsolved fundamental problem in binary evolution. To resolve this issue, we construct the thermal equilibrium mass loss model and derive critical mass ratios for both thermal timescale mass transfer and unstable mass transfer, the latter of which occurs when the outer Lagrangian point, L2, is overfilled. Using several 3.2 Msun stellar models as examples, we study the stellar response to thermal equilibrium mass loss and present the thresholds for thermal timescale mass transfer. We study the possible mass transfer channels of binary systems containing a 3.2 Msun donor star, taking into account thermal timescale mass transfer, unstable mass transfer through L2, and dynamical timescale mass transfer. We repeat this simulation for a grid of donor stars with different masses (from 0.1 to 100 Msun with Z = 0.02) and at different evolutionary stages, and present our results. The results show that unstable mass transfer due to the overfilling of the outer Lagrangian point may also play an essential role in the formation of common envelopes for late red giant branch and asymptotic giant branch donors.