The Fundamental Plane of the Broad-line Region in Active Galactic Nuclei

TL;DR

This paper establishes a fundamental plane relation linking broad-line region dynamics, accretion rates, and Fe II emission in active galactic nuclei, revealing many low-redshift quasars accrete at super-Eddington rates.

Contribution

It introduces the fundamental plane of the BLR, a new empirical relation connecting AGN properties using reverberation mapping data.

Findings

Strong bivariate correlation between accretion rate, Eddington ratio, and emission line ratios.

Super-Eddington accretion is common among low-redshift quasars.

The fundamental plane can be used to estimate accretion properties of AGNs.

Abstract

Broad emission lines in active galactic nuclei (AGNs) mainly arise from gas photoionized by continuum radiation from an accretion disk around a central black hole. The shape of the broad-line profile, described by ${\cal D}_{_{\rm H\beta}}={\rm FWHM}/\sigma_{_{\rm H\beta}}$, the ratio of full width at half maximum to the dispersion of broad H$\beta$, reflects the dynamics of the broad-line region (BLR) and correlates with the dimensionless accretion rate ($\dot{\mathscr{M}}$) or Eddington ratio ($L_{\rm bol}/L_{\rm Edd}$). At the same time, $\dot{\mathscr{M}}$ and $L_{\rm bol}/L_{\rm Edd}$ correlate with ${\cal R}_{\rm Fe}$, the ratio of optical Fe II to H$\beta$ line flux emission. Assembling all AGNs with reverberation mapping measurements of broad H$\beta$, both from the literature and from new observations reported here, we find a strong bivariate correlation of the form $\log(\dot{\mathscr{M}},L_{\rm bol}/L_{\rm Edd})=\alpha+\beta{\cal D}_{_{\rm H\beta}}+\gamma{\cal R}_{\rm Fe},$ where $\alpha=(2.47,0.31)$, $\beta=-(1.59,0.82)$ and $\gamma=(1.34,0.80)$. We refer to this as the fundamental plane of the BLR. We apply the plane to a sample of $z < 0.8$ quasars to demonstrate the prevalence of super-Eddington accreting AGNs are quite common at low redshifts.