NuSTAR observations of a heavily X-ray obscured AGN in the dwarf galaxy J144013+024744

Abstract

We present a multi-wavelength analysis of the dwarf Seyfert-2 galaxy J144013+024744, a candidate obscured active galactic nucleus (AGN) thought to be powered by an intermediate-mass black hole (IMBH, M ≈ 104-6 M) of mass M 105.2M. To study its X-ray properties, we targeted J144013+024744 with NuSTAR for ≈ 100 ks. The X-ray spectrum was fitted with absorbed power law, Pexmon and a physical model (RXTorus). A Bayesian X-ray analysis was performed to estimate the posteriors. The phenomenological and the physical models suggest the AGN to be heavily obscured by a column density of N H = (3.4-7.0)×1023 cm-2. In particular, the RXTorus model with a sub-solar metallicity suggests the obscuring column to be almost Compton-thick. We compared the 2-10 keV intrinsic X-ray luminosity with the inferred X-ray luminosities based on empirical scaling relations for unobscured AGNs using L [OIV](25.89μ m), L[ OIII](5007 angstrom), and L6 μ m and found that the high-excitation [ OIV] line provides a better estimate of the intrinsic 2-10 keV X-ray luminosity (L2-10 int 1041.41 erg s-1). Our results suggest that J144013+024744 is the first type-2 dwarf galaxy that shows X-ray spectroscopic evidence for obscuration. The column density that we estimated is among the highest measured to date for IMBH-powered AGNs, implying that a typical AGN torus geometry might extend to the low-mass end. This work has implications for constraining the black hole occupation fraction in dwarf galaxies using X-ray observations.