Showing papers by "Gordon P. Garmire published in 2021"

Clash of Titans: a MUSE dynamical study of the extreme cluster merger SPT-CLJ0307-6225

Abstract: We present VLT/MUSE spectroscopy, along with archival Gemini/GMOS spectroscopy, Magellan/Megacam imaging, and Chandra X-ray emission for SPT-CLJ0305-6225, a z=0.58 galaxy cluster. A large BCG-SZ centroid separation and a highly disturbed X-ray morphology classifies SPT-CLJ0307-6225 as a major merging cluster. Furthermore, the galaxy density distribution shows two main overdensities with separations of 0.144' and 0.017' to their respective BCGs. We characterize the central regions of the two colliding structures, namely 0307-6225N and 0307-6225S. We find velocity derived masses of $M_{200,N}=$ 2.42 $\pm$ 1.40 $\times10^{14}$ M$_\odot$ and $M_{200,S}=$ 3.13 $\pm$ 1.87 $\times10^{14}$ M$_\odot$, with a line-of-sight velocity difference between the two structures of $|\Delta v| = 342$ km s$^{-1}$. The total dynamically derived mass is consistent with the SZ derived mass of 7.63 h$_{70}^{-1}$ $\pm$ 1.36 $\times10^{14}$ M$_\odot$. We model the merger using the Monte Carlo Merger Analysis Code, estimating a merging angle of 36$^{+14}_{-12}$ degrees with respect to the plane of the sky. Comparing with simulations of a merging system with a mass ratio of 1:3, we find that the best scenario is that of an ongoing merger that began 0.96$^{+0.31}_{-0.18}$ Gyr ago, which could be close to turnaround. We also characterize the galaxy population using the H$\delta$ and [OII] $\lambda 3727$ \AA \ lines. We find that most of the emission-line galaxies belong to 0307-6225S, close to the X-ray peak position, with a third of them corresponding to red-cluster sequence galaxies, and the rest to blue galaxies with velocities consistent with recent periods of accretion. Moreover, we suggest that 0307-6225S suffered a previous merger, evidenced through the two equally bright BCGs at the center with a velocity difference of $\sim$674 km s$^{-1}$.

X-ray Super-Flares From Pre-Main Sequence Stars: Flare Modeling

Abstract: Getman et al. (2021) reports the discovery, energetics, frequencies, and effects on environs of $>1000$ X-ray super-flares with X-ray energies $E_X \sim 10^{34}-10^{38}$~erg from pre-main sequence (PMS) stars identified in the Chandra MYStIX and SFiNCs surveys. Here we perform detailed plasma evolution modeling of 55 bright MYStIX/SFiNCs super-flares from these events. This is the largest sample of highly energetic flares analyzed in a uniform fashion. They are compared with published X-ray super-flares from young stars in the Orion Nebula Cluster, older active stars, and the Sun. Several results emerge. First, the properties of PMS super-flares are independent of the presence or absence of protoplanetary disks, supporting the solar-type model of PMS flaring magnetic loops with both footpoints anchored in the stellar surface. Second, most PMS super-flares resemble solar long-duration events associated with coronal mass ejections. Slow rise PMS super-flares are an interesting exception. Third, strong correlations of super-flare peak emission measure and plasma temperature with the stellar mass are similar to established correlations for the PMS X-ray emission likely composed of numerous smaller flares. Fourth, a new correlation of loop geometry is linked to stellar mass; more massive stars have thicker flaring loops. Finally, the slope of a long-standing relationship between the X-ray luminosity and magnetic flux of various solar-stellar magnetic elements appears steeper in PMS super-flares than for solar events.