http://arxiv.org/abs/1803.08547
The existence of a large population of Compton thick (CT, $N_{H}>10^{24} cm^{-2}$) AGN is a key ingredient of Cosmic X-ray background synthesis models, and is required to match the observed AGN luminosity function with the local SMBH mass function. Direct identification of high-z CT-AGN is difficult, due to the flux suppression and complex spectral shape produced by CT obscuration. We explored the Chandra COSMOS Legacy point source catalog, to select, via X-ray spectroscopy, a large sample of CT-AGN, mostly at high redshift. Adopting a physical model for the toroidal CT reprocessor, and an MCMC approach, we selected 67 sources that have at least 5% probability of being CT, in the redshift range $0.04<z<3.5$. The sum of the probabilities above $N_{H}>10^{24} cm^{-2}$, gives a total of 38.5 ‘true’ CT-AGN. We derive the intrinsic $f_{CT}$ in three redshift bins and at different luminosities: at $log(L_X)=43.5$ erg/s, we found an increase from $f_{CT}=0.34$ at low z, consistent with the local value, to $f_{CT}=0.42$ at $z=1-2$ and $f_{CT}=0.54$ at $z=2-3.5$. The $f_{CT}$ evolution can be parametrized as $f_{CT}=0.27(1+z)^{0.52}$ at $log(L_X)=43.5$ erg/s and as $f_{CT}=0.14(1+z)^{0.92}$ at $log(L_X)=44.5$ erg/s. Finally, thanks to HST-ACS deep imaging, we found that the fraction of CT-AGN in mergers increases with luminosity and is significantly higher than in typical AGN hosts.
G. Lanzuisi, F. Civano, S. Marchesi, et. al.
Mon, 26 Mar 18
1/43
Comments: 15 pages, 12 figures. Submitted to MNRAS
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