The Radiative Efficiency of Accretion Flows in Individual AGN

Abstract

The radiative efficiency of AGN is commonly estimated based on the total mass accreted and the total AGN light emitted per unit volume in the universe integrated over time (the Soltan argument). In individual AGN, thin accretion disk model spectral fits can be used to deduce the absolute accretion rate Mdot, if the black hole mass M is known. The radiative efficiency η is then set by the ratio of the bolometric luminosity Lbol to Mdot c2. We apply this method to determine η in a sample of 80 PG quasars with well determined Lbol, where Mdot is set by thin accretion disk model fits to the optical luminosity density, and the M determination based on the bulge stellar velocity dispersion (13 objects) or the broad line region (BLR). For the BLR-based masses, we derive a mean log η = -1.05 +/- 0.52 consistent with the Soltan argument based estimates. We find a strong correlation of η with M, rising from η ~ 0.03 at M = 107 M and L/LEdd ~ 1 to η ~ 0.4 at M = 109 M and L/LEdd ~ 0.3. This trend is related to the overall uniformity of Lopt/Lbol in our sample, particularly the lack of the expected increase in Lopt/Lbol with increasing M (and decreasing L/LEdd), which is a generic property of thermal disk emission at fixed η. The significant uncertainty in the M determination is not large enough to remove the correlation. The rising η with M may imply a rise in the black hole spin with M, as proposed based on other indirect arguments.