Analysis of eight magnetic chemically peculiar stars with rotational modulation

TL;DR

This study uses TESS data to analyze rotational modulation in eight magnetic chemically peculiar stars, determining their rotation periods and examining the relationship between stellar age and rotational velocity.

Contribution

First application of TESS photometry to derive rotation periods and magnetic field correlations in a sample of mCP stars, revealing magnetic braking effects.

Findings

All eight stars' rotation periods were successfully determined.

Phased light curves and magnetic measurements show consistent variability.

Critical rotational fraction decreases with stellar age, indicating magnetic braking.

Abstract

Since the end of 2018, the Transiting Exoplanet Survey Satellite (TESS) has provided stellar photometry to the astronomical community. We have used TESS data to study rotational modulation in the light curves of a sample of chemically peculiar stars with measured large-scale magnetic fields (mCP stars). In general, mCP stars show inhomogeneous distributions of elements in their atmospheres that lead to spectroscopic (line profile) and photometric (light curve) variations commensurate with the rotational period. We analyzed the available TESS data from 50 sectors for eight targets after post-processing them in order to minimize systematic instrumental trends. Analysis of the light curves allowed us to determine rotational periods for all eight of our targets. For each star, we provide a phase diagram calculated using the derived period from the light curves and from the available measurements of the disk-averaged longitudinal magnetic field $\langle B_{\rm z}\rangle$. In most cases, the phased light curve and $\langle B_{\rm z}\rangle$ measurements show consistent variability. Using our rotation periods, and global stellar parameters derived from fitting Balmer line profiles, and from Geneva and Str\"omgren-Crawford photometry, we determined the equatorial rotational velocities and calculated the respective critical rotational fractions $v_{\rm eq}/v_{\rm crit}$. We have shown from our sample that the critical rotational fraction decreases with stellar age, at a rate consistent with the magnetic braking observed in the larger population of mCP stars.