Suzaku Observation of HCG 62: Temperature, Abundance, and Extended Hard X-ray Emission Profiles

TL;DR

This study used Suzaku X-ray observations to analyze the temperature, elemental abundances, and extended hard X-ray emission in galaxy group HCG 62, confirming its multi-temperature structure and setting limits on hard X-ray excess.

Contribution

First detailed Suzaku analysis of HCG 62 revealing its multi-temperature intra-group medium and constraining extended hard X-ray emission with improved background modeling.

Findings

Confirmed multi-temperature nature of the intra-group medium.

Did not detect extended hard X-ray emission previously reported.

Estimated metal abundances and mass-to-light ratios.

Abstract

We present results of 120 ks observation of a compact group of galaxies HCG~62 ($z=0.0145$) with Suzaku XIS and HXD-PIN\@. The XIS spectra for four annular regions were fitted with two temperature {\it vapec} model with variable abundance, combined with the foreground Galactic component. The Galactic component was constrained to have a common surface brightness among the four annuli, and two temperature {\it apec} model was preferred to single temperature model. We confirmed the multi-temperature nature of the intra-group medium reported with Chandra and XMM-Newton, with a doughnut-like high temperature ring at radii 3.3--6.5$'$ in a hardness image. We found Mg, Si, S, and Fe abundances to be fairly robust. We examined the possible ``high-abundance arc'' at $\sim 2'$ southwest from the center, however Suzaku data did not confirm it. We suspect that it is a misidentification of an excess hot component in this region as the Fe line. Careful background study showed no positive detection of the extended hard X-rays previously reported with ASCA, in 5--12 keV with XIS and 12--40 keV with HXD-PIN, although our upper limit did not exclude the ASCA result. There is an indication that the X-ray intensity in $r<3.3'$ region is $70\pm 19$% higher than the nominal CXB level (5--12 keV), and Chandra and Suzaku data suggest that most of this excess could be due to concentration of hard X-ray sources with an average photon index of $\Gamma=1.38\pm 0.06$. Cumulative mass of O, Fe and Mg in the group gas and the metal mass-to-light ratio were derived and compared with those in other groups. Possible role of AGN or galaxy mergers in this group is also discussed.