Multiwavelength Scrutiny of X-ray Sources in Dwarf Galaxies: ULXs versus AGN

TL;DR

This study uses high-resolution multiwavelength observations to distinguish between X-ray binaries and active galactic nuclei in dwarf galaxies, revealing that some previously identified AGN candidates are likely X-ray binaries.

Contribution

It provides detailed multiwavelength analysis of dwarf galaxy X-ray sources, challenging previous AGN identifications and exploring the nature of luminous X-ray sources and their environments.

Findings

Two galaxies host off-nuclear X-ray sources likely to be X-ray binaries.

One galaxy contains a complex source with potential AGN or ULX interpretation.

He II emission suggests the X-ray source was more luminous in the past.

Abstract

Owing to their quiet evolutionary histories, nearby dwarf galaxies (stellar masses $M_\star \lesssim 3 \times 10^9 M_\odot$) have the potential to teach us about the mechanism(s) that 'seeded' the growth of supermassive black holes, and also how the first stellar mass black holes formed and interacted with their environments. Here, we present high spatial-resolution observations of three dwarf galaxies in the X-ray (Chandra), the optical/near-infrared (Hubble Space Telescope), and the radio (Karl G. Jansky Very Large Array). These three galaxies were previously identified as hosting candidate active galactic nuclei on the basis of lower resolution X-ray imaging. With our new observations, we find that X-ray sources in two galaxies (SDSS J121326.01+543631.6 and SDSS J122111.29+173819.1) are off nuclear and lack corresponding radio emission, implying they are likely luminous X-ray binaries. The third galaxy (Mrk 1434) contains two X-ray sources (each with $L_{\rm X} \approx 10^{40}$ erg s$^{-1}$) separated by 2".8, has a low metallicity (12 + log (O/H) = 7.8), and emits nebular \ion{He}{II} $\lambda$4686 line emission. The northern source has spatially coincident point-like radio emission at 9.0 GHz and extended radio emission at 5.5 GHz. We discuss X-ray binary interpretations (where an ultraluminous X-ray source blows a 'radio bubble') and active galactic nucleus interpretations (where a $\approx 4\times10^5 M_\odot$ black hole launches a jet). In either case, we find that the \ion{He}{II} emission cannot be photoionised by the X-ray source, unless the source was $\approx$30-90 times more luminous several hundred years ago.