On the Evolution of High-Redshift Active Galactic Nuclei

Abstract

We build a simple physical model to study the high-redshift active galactic Nucleus (AGN) evolution within the co-evolution framework of central black holes (BHs) and their host galaxies. The correlation between the circular velocity of a dark halo Vc and the velocity dispersion of a galaxy σ is used to link the dark matter halo mass and BH mass. The dark matter halo mass function is converted to the BH mass function for any given redshift. The high-redshift optical AGN luminosity functions (LFs) are constructed. At z 4, the flattening feature is not shown at the faint end of the optical AGN LF. This is consistent with observational results. If the optical AGN LF at z 6 can be reproduced in the case in which central BHs have the Eddington-limited accretion, it is possible for the AGN lifetime to have a small value of 2× 105 yrs. The X-ray AGN LFs and X-ray AGN number counts are also calculated at 2.0<z<5.0 and z>3, respectively, using the same parameters adopted in the calculation for the optical AGN LF at z 4. It is estimated that about 30 AGNs per deg2 at z>6 can be detected with a flux limit of 3× 10-17~erg~cm-2~s-1 in the 0.5-2 keV band. Additionally, the cosmic reionization is also investigated. The ultraviolet photons emitted from the high-redshift AGNs mainly contribute to the cosmic reionization, and the central BHs of the high-redshift AGNs have a mass range of 106-108M. We also discuss some uncertainties in both the AGN LFs and AGN number counts originating from the MBH-σ relation, Eddington ratio, AGN lifetime, and X-ray attenuation in our model.