Chandra observations of NGC4342, an optically faint, X-ray gas-rich early-type galaxy

TL;DR

Chandra X-ray observations reveal that NGC4342, a low-mass early-type galaxy, hosts hot gas with disturbed morphology due to ram pressure, and likely contains a large population of globular clusters inferred from excess X-ray sources.

Contribution

This study provides the first detailed analysis of hot gas dynamics and globular cluster population estimates in NGC4342 using X-ray and optical data.

Findings

Hot gas temperature ~0.6 keV with broad distribution

NGC4342 moves supersonically (~2.6 Mach) through external gas

Estimated 850-1700 globular clusters in NGC4342

Abstract

Chandra X-ray observations of NGC4342, a low stellar mass (M_K=-22.79 mag) early-type galaxy, show luminous, diffuse X-ray emission originating from hot gas with temperature of kT~0.6 keV. The observed 0.5-2 keV band luminosity of the diffuse X-ray emission within the D_25 ellipse is L_0.5-2keV = 2.7 x 10^39 erg/s. The hot gas has a significantly broader distribution than the stellar light, and shows strong hydrodynamic disturbances with a sharp surface brightness edge to the northeast and a trailing tail. We identify the edge as a cold front and conclude that the distorted morphology of the hot gas is produced by ram pressure as NGC4342 moves through external gas. From the thermal pressure ratios inside and outside the cold front, we estimate the velocity of NGC4342 and find that it moves supersonically (M~2.6) towards the northeast. Outside the optical extent of the galaxy we detect ~17 bright (L_0.5-8keV > 3 x 10^37 erg/s) excess X-ray point sources. The excess sources are presumably low-mass X-ray binaries (LMXBs) located in metal-poor globular clusters (GCs) in the extended dark matter halo of NGC4342. Based on the number of excess sources and the average frequency of bright LMXBs in GCs, we estimate that NGC4342 may host roughly 850-1700 GCs. In good agreement with this, optical observations hint that NGC4342 may harbor 1200 +/- 500 GCs. This number corresponds to a GC specific frequency of S_N = 19.9 +/- 8.3, which is among the largest values observed in full-size galaxies.