The Black Hole Masses and Eddington Ratios of Type 2 Quasars

Abstract

Type 2 quasars are an important constituent of active galaxies, possibly representing the evolutionary precursors of traditionally studied type 1 quasars. We characterize the black hole mass (M BH) and Eddington ratio (L bol/L Edd) for 669 type 2 quasars selected from the Sloan Digital Sky Survey, using black hole masses estimated from the M BH-σ relation and bolometric corrections scaled from the extinction-corrected [ O~ III]~ λ 5007 luminosity. When stellar velocity dispersions cannot be measured directly from the spectra, we estimate them from the core velocity dispersions of the narrow emission lines [O~ II]~ λλ 3726, 3729, [S~ II]~λλ 6716, 6731, and [ O~ III]~ λ 5007, which are shown to trace the gravitational potential of the stars. Energy input from the active nucleus still imparts significant perturbations to the gas kinematics, especially to high-velocity, blueshifted wings. Nonvirial motions in the gas become most noticeable in systems with high Eddington ratios. The black hole masses of our sample of type 2 quasars range from M BH ≈ 106.5 to 1010.4 \, M (median 108.2 \, M). Type 2 quasars have characteristically large Eddington ratios (L bol/L Edd~≈ 10-2.9-101.8; median 10-0.7), slightly higher than in type~1 quasars of similar redshift; the luminosities of 20% of the sample formally exceed the Eddington limit. The high Eddington ratios may be consistent with the notion that obscured quasars evolve into unobscured quasars.