NewEvery arXiv paper, its researchers & institutions — mapped.
paper

Turbulent convection and pulsation stability of stars - II. Theoretical instability strip for $δ$ Scuti and $γ$ Doradus stars

arXiv:1808.09621 · doi:10.1093/mnras/stw047

Abstract

By using a non-local and time-dependent convection theory, we have calculated radial and low-degree non-radial oscillations for stellar evolutionary models with $M=1.4$--3.0\,$\mathrm{M}_\odot$. The results of our study predict theoretical instability strips for $δ$ Scuti and $γ$ Doradus stars, which overlap with each other. The strip of $γ$ Doradus is slightly redder in colour than that of $δ$ Scuti. We have paid great attention to the excitation and stabilization mechanisms for these two types of oscillations, and we conclude that radiative $κ$ mechanism plays a major role in the excitation of warm $δ$ Scuti and $γ$ Doradus stars, while the coupling between convection and oscillations is responsible for excitation and stabilization in cool stars. Generally speaking, turbulent pressure is an excitation of oscillations, especially in cool $δ$ Scuti and $γ$ Doradus stars and all cool Cepheid- and Mira-like stars. Turbulent thermal convection, on the other hand, is a damping mechanism against oscillations that actually plays the major role in giving rise to the red edge of the instability strip. Our study shows that oscillations of $δ$ Scuti and $γ$ Doradus stars are both due to the combination of $κ$ mechanism and the coupling between convection and oscillations, and they belong to the same class of variables at the low-luminosity part of the Cepheid instability strip. Within the $δ$ Scuti--$γ$ Doradus instability strip, most of the pulsating variables are very likely hybrids that are excited in both p and g modes.

16 pages, 20 figures, published 2016 February 19