The RS CVn type star GT Mus shows most energetic X-ray flares throughout the 2010s

TL;DR

This study identifies GT Mus as the most X-ray energetic star in the last decade, documenting 11 large flares with detailed analysis of their properties, energies, and cooling mechanisms, highlighting its extreme stellar activity.

Contribution

It provides the first comprehensive analysis of recurrent energetic X-ray flares from GT Mus, including detailed timing, energy, and cooling process characterizations, expanding understanding of stellar flare energetics.

Findings

GT Mus produced 11 energetic X-ray flares over 8 years.

Flares had peak luminosities of 1-4 x 10^{33} erg/s.

Flares released energies up to 1-11 x 10^{38} erg.

Abstract

We report that the RS CVn-type star GT Mus (HR 4492, HD 101379 + HD 101380) was the most active star in the X-ray sky in the last decade in terms of the scale of recurrent energetic flares. We detected 11 flares from GT Mus in 8 yr of observations with Monitor of All-sky X-ray Image (MAXI) from 2009 August to 2017 August. The detected flare peak luminosities were 1-4 $\times$ 10$^{33}$ erg s$^{-1}$ in the 2.0-20.0 keV band for its distance of 109.6 pc. Our timing analysis showed long durations ($\tau_{\rm r} + \tau_{\rm d}$) of 2-6 days with long decay times ($\tau_{\rm d}$) of 1-4 days. The released energies during the decay phases of the flares in the 0.1-100 keV band ranged 1-11 $\times$ 10$^{38}$ erg, which are at the upper end of the observed stellar flare. The released energies during whole duration time ranged 2-13 $\times$ 10$^{38}$ erg in the same band. We carried out X-ray follow-up observations for one of the 11 flares with Neutron star Interior Composition Explorer (NICER) on 2017 July 18 and found that the flare cooled quasi-statically. On the basis of a quasi-static cooling model, the flare loop length is derived to be 4 $\times$ 10$^{12}$ cm (or 60 R$_{\odot}$). The electron density is derived to be 1 $\times$ 10$^{10}$ cm$^{-3}$, which is consistent with the typical value of solar and stellar flares (10$^{10-13}$ cm$^{-3}$). The ratio of the cooling timescales between radiative cooling ($\tau_{\rm rad}$) and conductive cooling ($\tau_{\rm cond}$) is estimated to be $\tau_{\rm rad}$ $\sim$ 0.1$\tau_{\rm cond}$ from the temperature; thus radiative cooling was dominant in this flare.