The Dependence of the Mean Spectral Energy Distributions on the Accretion Rate for Quasars with z < 0.75 from the Sloan Digital Sky Survey

Abstract

We construct mean spectral energy distributions (SEDs) for a substantial sample of 56,969 Sloan Digital Sky Survey DR16 quasars with z < 0.75, utilizing multiwavelength data from the mid-infrared (MIR) to ultraviolet (UV). These SEDs are built on eigenvector 1 parameters -- the relative optical Fe~ II strength (R Fe~II) and the Hβ line width ( Hβ) -- that capture the principal spectral variance of quasar spectra. From three R Fe~II-dependent mean SEDs we find that quasars with a larger R Fe~II exhibit redder UV and optical and redder MIR and near-infrared (NIR) continua, indicating more dust emission. We also split our sample directly into Eddington ratio L Bol /L Edd (or dimensionless accretion rate M) bins to construct different mean SEDs and find that the continua become increasingly red with increasing L Bol /L Edd (or M) in the MIR, NIR, and UV bands. This demonstrates that the shapes of Type 1 AGN SEDs depend on the accretion rate. However, the optical continuum shows the opposite trend (becoming harder and bluer), indicating the complexity of the optical emission region. From FWHMHβ-dependent mean SEDs we find that quasars with a larger FWHMHβ show redder optical and NIR continua and bluer UV and MIR continua. The bluer MIR continuum suggests that a larger angle between of the line of sight and the torus plane results in weaker torus emission in the MIR.