KIC 10526294: a slowly rotating B star with rotationally split, quasi-equally spaced gravity modes

TL;DR

This study presents a detailed asteroseismic analysis of the slowly rotating B star KIC 10526294, revealing its internal rotation profile, core overshooting, and pulsation modes using Kepler data, thereby enhancing understanding of massive star interiors.

Contribution

It provides the first detailed seismic constraints on a slow rotator B star, including its internal rotation profile and core overshooting, using extensive Kepler data and spectral analysis.

Findings

Detected 19 quasi-equally spaced dipole modes

Resolved narrow rotationally split multiplets

Indicated a non-rigid internal rotation profile

Abstract

Massive stars are important for the chemical enrichment of the universe. Since internal mixing processes influence their lives, it is very important to place constraints on the corresponding physical parameters, such as core overshooting and the internal rotation profile, so as to calibrate their stellar structure and evolution models. Although asteroseismology has been shown to be able to deliver the most precise constraints so far, the number of detailed seismic studies delivering quantitative results is limited. Our goal is to extend this limited sample with an in-depth case study and provide a well-constrained set of asteroseismic parameters, contributing to the ongoing mapping efforts of the instability strips of the beta Cep and SPB stars. We derived fundamental parameters from high-resolution spectra using spectral synthesis techniques. We used custom masks to obtain optimal light curves from the original pixel level data from the Kepler satellite. We used standard time-series analysis tools to construct a set of significant pulsation modes that provide the basis for the seismic analysis carried out afterwards. We find that KIC 10526294 is a cool SPB star, one of the slowest rotators ever found. Despite this, the length of Kepler observations is sufficient to resolve narrow rotationally split multiplets for each of its 19 quasi-equally spaced dipole modes. The number of detected consecutive (in radial order) dipole modes in this series is higher than ever before. The observed amount of splitting shows an increasing trend towards longer periods, which - largely independent of the seismically calibrated stellar models - points towards a non-rigid internal rotation profile. From the average splitting we deduce a rotation period of ~188 d. From seismic modelling, we find that the star is young with a central hydrogen mass fraction X_c>0.64; it has a core overshooting alpha_ov<=0.15.