The cosmological evolution of quasar black-hole masses
Abstract
Virial black-hole mass estimates are presented for 12698 quasars in the redshift interval 0.1<z<2.1, based on modelling of spectra from the Sloan Digital Sky Survey (SDSS) first data release. The black-hole masses of the SDSS quasars are found to lie between 107 and an upper limit of 3× 109, entirely consistent with the largest black-hole masses found to date in the local Universe. The estimated Eddington ratios of the broad-line quasars (FWHM≥ 2000 kms-1) show a clear upper boundary at Lbol/LEdd 1, suggesting that the Eddington luminosity is still a relevant physical limit to the accretion rate of luminous broad-line quasars at z≤ 2. By combining the black-hole mass distribution of the SDSS quasars with the 2dF quasar luminosity function, the number density of active black holes at z 2 is estimated as a function of mass. In addition, we independently estimate the local black-hole mass function for early-types using the Mbh-σ and Mbh-Lbulge correlations. Based on the SDSS velocity dispersion function and the 2MASS K-band luminosity function, both estimates are found to be consistent at the high-mass end (Mbh≥ 108). By comparing the estimated number density of active black holes at z 2 with the local mass density of dormant black holes, we set lower limits on the quasar lifetimes and find that the majority of black holes with mass ≥ 108.5 are in place by 2.
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