Radiative Efficiency of Disk Accretion in Individual SDSS QSOs

Abstract

We estimate the radiative efficiency (epsilon) of individual type 1 SDSS QSOs by using their bolometric luminosities (Lbol) and accretion rates (M,acc), which may be related to the assembly histories and spins of the central massive black holes (MBHs). We estimate Lbol by using the empirical spectral energy distributions of QSOs and M,acc by fitting the observed optical luminosity(/-ies) with the thin accretion disk model, assuming the MBH masses given by the virial mass estimator(s) (M,vir). We find an apparent correlation between epsilon and M,vir, which is strong at redshift z 1.8, weak at z 2, and consistent with that found by Davis & Laor (2011) for 80 PG QSOs at z ≤ 0.5. To investigate whether this correlation is intrinsic or not, we construct a mock sample of QSOs according to the true MBH mass and Eddington ratio distributions given in Kelly & Shen (2013). By comparing the results obtained from the mock sample with that from the SDSS sample, we demonstrate that the apparent epsilon-M,vir correlation can be produced by and mainly due to the selection effects of the SDSS sample and the bias induced by the usage of M,vir as the true MBH mass. The mean values of epsilon of those SDSS QSOs are consistent with being a constant 0.11-0.16 over the redshift range of 0.3 z 4. We conclude that the current SDSS QSO data is consistent with no strong intrinsic correlation between radiative efficiency and true MBH mass and no significant redshift evolution of radiative efficiencies.