Variability of magnetic hot stars from the TESS observations

TL;DR

This study analyzes the photometric variability of 118 magnetic hot stars using TESS data, identifying new variable stars and exploring the relationship between magnetic fields and stellar variability.

Contribution

It provides the first large-scale variability analysis of magnetic hot stars combining TESS data with Bayesian modeling, revealing new insights into their stochastic low frequency variability.

Findings

Identified 9 new rotating variable stars.

Most stars have gamma between 1 and 3.

Negative correlation between magnetic field strength and characteristic frequency.

Abstract

Magnetic hot stars refer to the stars, which effective temperatures approximately in the range from 7,000 to 50,000 K, and with large-scale globally organized magnetic fields. These magnetic fields exhibit strengths ranging from tens of Gauss to tens of kilo-Gauss. They are key in understanding the effects caused by magnetic fields in the stellar evolution. However, there are only three magnetic hot stars studied via a combination of spectropolarimetric and asteroseismic modeling. Combined with $Transiting\;Exoplanet\;Survey\;Satellite\;(TESS)$ 1-56 sectors data sets, we provided a photometric variability and stochastic low frequency (SLF) variability study of 118 magnetic hot stars. 9 new rotating variable stars are identified. Using the Bayesian Markov Chain Monte Carlo (MCMC) framework, we fitted the morphologies of SLF variability for magnetic hot stars. Our analysis reveals that the magnetic hot stars in our sample have $\gamma < 5.5$ with the vast majority having $1 \leq \gamma \leq 3$. The $\nu_{\rm char}$ is primarily in the ranges of $0\;\text{d}^{-1} < \nu_{\rm char} < 6.3\;\text{d}^{-1}$. The amplitude of SLF variability, log$\alpha_{\rm 0}$, shows a dominant distribution ranging from 0.8 to 3. No significant correlations are observed between the luminosity and fitting parameters, suggesting no clear dependence of SLF variability on stellar mass for our sample of magnetic hot stars with masses between approximately $1.5 M_{\odot}< M < 20 M_{\odot}$. We found a significant negative correlation between the $B_{\rm p}$ and $\nu_{char}$. This suppression effect of magnetic fields on $\nu_{\rm char}$ may be a result of their inhibition of macroturbulence.