The roAp star $\alpha$ Circini as seen by BRITE-Constellation

TL;DR

This study uses high-precision, multi-colour photometry from BRITE-Constellation to analyze the pulsation and surface features of the bright roAp star $ extalpha$ Cir, revealing stable pulsation frequencies, surface spots, and band-dependent light variations.

Contribution

First detailed multi-colour photometric analysis of $ extalpha$ Cir using BRITE data, revealing surface spots and pulsation stability over 20 years.

Findings

Detection of two large-scale bright spots on $ extalpha$ Cir.

Confirmation of main pulsation frequency stability over 20 years.

Exclusion of quadrupolar modes for the main pulsation frequency.

Abstract

We report on an analysis of high-precision, multi-colour photometric observations of the rapidly-oscillating Ap (roAp) star $\alpha$ Cir. These observations were obtained with the BRITE-Constellation, which is a coordinated mission of five nanosatellites that collects continuous millimagnitude-precision photometry of dozens of bright stars for up to 180 days at a time in two colours (Johnson B and R). BRITE stands for BRight Target Explorer. The object $\alpha$ Cir is the brightest roAp star and an ideal target for such investigations, facilitating the determination of oscillation frequencies with high resolution. This star is bright enough for complementary interferometry and time-resolved spectroscopy. Four BRITE satellites observed $\alpha$ Cir for 146 d or 33 rotational cycles. Phasing the photometry according to the 4.4790 d rotational period reveals qualitatively different light variations in the two photometric bands. The phased red-band photometry is in good agreement with previously-published WIRE data, showing a light curve symmetric about phase 0.5 with a strong contribution from the first harmonic. The phased blue-band data, in contrast, show an essentially sinusoidal variation. We model both light curves with Bayesian Photometric Imaging, which suggests the presence of two large-scale, photometrically bright (relative to the surrounding photosphere) spots. We also examine the high-frequency pulsation spectrum as encoded in the BRITE photometry. Our analysis establishes the stability of the main pulsation frequency over the last 20 years, confirms the presence of frequency f7, which was not detected (or the mode not excited) prior to 2006, and excludes quadrupolar modes for the main pulsation frequency.