Short-term variability and mass loss in Be stars I. BRITE satellite photometry of $\eta$ and $\mu$ Centauri

TL;DR

This study uses BRITE satellite photometry to investigate short-term variability and mass loss mechanisms in Be stars ta and mu Centauri, revealing complex star-disk interactions driven by nonradial pulsations.

Contribution

It provides new insights into the coupling of pulsation modes, mass transfer, and circumstellar activity in Be stars through combined photometry and spectroscopy.

Findings

Mass transfer is modulated by the frequency difference of two NRP modes.

Circumstellar activity correlates with the Stefl frequency and its amplitude.

Gas-circulation flows at the star-disk interface produce observable Stefl frequencies.

Abstract

Empirical evidence for the involvement of nonradial pulsations (NRP's) in the mass loss from Be stars ranges from (i) a singular case (\object{$\mu$ Cen}) of repetitive mass ejections triggered by multi-mode beating to (ii) several photometric reports about enormous numbers of pulsation modes popping up during outbursts and on to (iii) effective single-mode pulsators. The BRITE Constellation of nanosatellites was used to obtain mmag photometry of the Be stars $\eta$ and \object{$\mu$ Cen}. In the low-inclination star \object{$\mu$ Cen}, light pollution by variable amounts of near-stellar matter prevented any new insights into the variability and other properties of the central star. In the equator-on star \object{$\eta$ Cen}, BRITE photometry and {\sc Heros} echelle spectroscopy from the 1990s reveal an intricate clockwork of star-disk interactions. The mass transfer is modulated with the frequency difference of two NRP modes and an amplitude three times as large as the amplitude sum of the two NRP modes. This process feeds a high-amplitude circumstellar activity running with the incoherent and slightly lower so-called \v{S}tefl frequency. The mass loss-modulation cycles are tightly coupled to variations in the value of the \v{S}tefl frequency and in its amplitude, albeit with strongly drifting phase differences. The observations are well described by the decomposition of the mass loss into a pulsation-related engine in the star and a viscosity-dominated engine in the circumstellar disk. Arguments are developed that large-scale gas-circulation flows occur at the interface. The propagation rates of these eddies manifest themselves as \v{S}tefl frequencies. Bursts in power spectra during mass-loss events can be understood as the noise inherent to these gas flows.