A thin disk and a nearly universal accretion rate in luminous quasars

TL;DR

This paper demonstrates that luminous quasars exhibit remarkably similar spectra due to a nearly constant Eddington ratio and standard accretion disk emission, simplifying black hole mass and luminosity estimates.

Contribution

It shows that a standard accretion disk with a fixed Eddington ratio explains quasar spectral uniformity and improves black hole mass estimation accuracy.

Findings

Quasars have a nearly constant Eddington ratio of 0.1.

Spectral energy distributions peak beyond the ultraviolet for most quasars.

Line-to-continuum luminosity relations support the standard disk model.

Abstract

Quasars accretion models predict a broad range of optical and ultraviolet properties that depend primarily on black hole mass and accretion rate. Yet, most optically selected luminous quasars display strikingly similar continuum spectra. We show that this uniformity can be explained by a nearly constant luminosity to mass (Eddington) ratio, L_EDD and by thermal emission from a standard, optically thick, geometrically thin accretion disc. A standard disk with an Eddington ratio L_EDD=0.1 reproduces both the black hole mass/luminosity distribution of Sloan Digital Sky Survey (SDSS) quasars and their principal continuum properties. In this framework, the spectral energy distribution peaks beyond the observable ultraviolet range for nearly all sources. We show that the few quasars, expected to be cold enough to shift the peak into the observable region, indeed show this behaviour. This scenario is further supported by an analysis of the relation between the luminosity of the main broad emission lines and the continuum luminosity (i.e. the Baldwin effect). We find that 1) the observed slopes of the line to continuum relations match the expectations from the standard disk model, if we assume that the line emission is a good proxy of the ionizing luminosity; 2) the dispersions of the line-continuum luminosity relations are very small (as small as 0.13 dex), suggesting that the physics of the disk-broad line region system is dominated by only one parameter (the black hole mass) with a nearly constant Eddington ratio. Finally, we notice that our hypothesis of constant L_EDD=0.1 provides a black hole mass estimate (based on the observed luminosity) with a smaller error than the virial estimate.