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Heavy X-ray obscuration in the most-luminous galaxies discovered by WISE

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 Added by Fabio Vito
 Publication date 2017
  fields Physics
and research's language is English




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Hot Dust-Obscured Galaxies (Hot DOGs) are hyperluminous ($L_{mathrm{8-1000,mu m}}>10^{13},mathrm{L_odot}$) infrared galaxies with extremely high (up to hundreds of K) dust temperatures. The sources powering both their extremely high luminosities and dust temperatures are thought to be deeply buried and rapidly accreting supermassive black holes (SMBHs). Hot DOGs could therefore represent a key evolutionary phase in which the SMBH growth peaks. X-ray observations can be used to study their obscuration levels and luminosities. In this work, we present the X-ray properties of the 20 most-luminous ($L_{mathrm{bol}}gtrsim10^{14}, L_odot$) known Hot DOGs at $z=2-4.6$. Five of them are covered by long-exposure ($10-70$ ks) Chandra and XMM-Newton observations, with three being X-ray detected, and we study their individual properties. One of these sources (W0116$-$0505) is a Compton-thick candidate, with column density $N_H=(1.0-1.5)times10^{24},mathrm{cm^{-2}}$ derived from X-ray spectral fitting. The remaining 15 Hot DOGs have been targeted by a Chandra snapshot (3.1 ks) survey. None of these 15 is individually detected; therefore we applied a stacking analysis to investigate their average emission. From hardness-ratio analysis, we constrained the average obscuring column density and intrinsic luminosity to be log$N_H,mathrm{[cm^{-2}]}>23.5$ and $L_Xgtrsim10^{44},mathrm{erg,cm^{-2},s^{-1}}$, which are consistent with results for individually detected sources. We also investigated the $L_X-L_{6mumathrm{m}}$ and $L_X-L_{bol}$ relations, finding hints that Hot DOGs are typically X-ray weaker than expected, although larger samples of luminous obscured QSOs are needed to derive solid conclusions.



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We present a large sample of infrared-luminous candidate active galactic nuclei (AGNs) that lack X-ray detections in Chandra, XMM-Newton, and NuSTAR fields. We selected all optically detected SDSS sources with redshift measurements, combined additional broadband photometry from WISE, UKIDSS, 2MASS, and GALEX, and modeled the spectral energy distributions (SEDs) of our sample sources. We parameterize nuclear obscuration in our SEDs with $E(B!-!V)_{text{AGN}}$ and uncover thousands of powerful obscured AGNs that lack X-ray counterparts, many of which are identified as AGN candidates based on straightforward WISE photometric criteria. Using the observed luminosity correlation between restframe 2-10 keV ($L_{text{X}}$) and restframe AGN 6 $mu{text{m}}$ ($L_{text{MIR}}$), we estimate the intrinsic X-ray luminosities of our sample sources and combine these data with flux limits from X-ray catalogs to determine lower limits on nuclear obscuration. Using the ratio of intrinsic-to-observed X-ray luminosity ($R_{L_{text{X}}}$), we find a significant fraction of sources with column densities approaching $N_{text{H}}>$ 10$^{text{24}}$ cm$^{-{text{2}}}$, suggesting that multiwavelength observations are necessary to account for the population of heavily obscured AGNs. We simulate the underlying $N_{text{H}}$ distribution for the X-ray non-detected sources in our sample through survival analysis, and confirm the presence of AGN activity via X-ray stacking. Our results point to a considerable population of extremely obscured AGNs undetected by current X-ray observatories.
The merger of two or more galaxies can enhance the inflow of material from galactic scales into the close environments of Active Galactic Nuclei (AGN), obscuring and feeding the supermassive black hole (SMBH). Both recent simulations and observations of AGN in mergers have confirmed that mergers are related to strong nuclear obscuration. However, it is still unclear how AGN obscuration evolves in the last phases of the merger process. We study a sample of 60 Luminous and Ultra-luminous IR galaxies (U/LIRGs) from the GOALS sample observed by NuSTAR. We find that the fraction of AGN that are Compton-thick (CT; $N_{rm H}geq 10^{24}rm,cm^{-2}$) peaks at $74_{-19}^{+14}%$ at a late merger stage, prior to coalescence, when the nuclei have projected separations of $d_{rm sep}sim 0.4-6$ kpc. A similar peak is also observed in the median $N_{rm H}$ [$(1.6pm0.5)times10^{24}rm,cm^{-2}$]. The vast majority ($85^{+7}_{-9}%$) of the AGN in the final merger stages ($d_{rm sep}lesssim 10$ kpc) are heavily obscured ($N_{rm H}geq 10^{23}rm,cm^{-2}$), and the median $N_{rm H}$ of the accreting SMBHs in our sample is systematically higher than that of local hard X-ray selected AGN, regardless of the merger stage. This implies that these objects have very obscured nuclear environments, with the $N_{rm H}geq 10^{23}rm,cm^{-2}$ gas almost completely covering the AGN in late mergers. CT AGN tend to have systematically higher absorption-corrected X-ray luminosities than less obscured sources. This could either be due to an evolutionary effect, with more obscured sources accreting more rapidly because they have more gas available in their surroundings, or to a selection bias. The latter scenario would imply that we are still missing a large fraction of heavily obscured, lower luminosity ($L_{2-10}lesssim 10^{43}rm,erg,s^{-1}$) AGN in U/LIRGs.
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