The effect of radiation pressure on emission line profiles and black hole mass determination in active galactic nuclei

TL;DR

This paper investigates how radiation pressure influences emission line profiles and black hole mass estimates in active galactic nuclei, proposing a refined mass estimation method that accounts for radiation effects and cloud populations.

Contribution

It introduces a new analysis incorporating radiation pressure into BLR cloud dynamics and proposes an improved black hole mass estimation formula considering radiation effects.

Findings

Virial mass estimates remain reasonable despite radiation pressure effects.

At least two cloud populations are needed to reproduce observed line properties.

A new mass estimation formula involving luminosity and FWHM is proposed.

Abstract

We present a new analysis of the motion of broad line region (BLR) clouds in active galactic nuclei (AGNs) taking into account the combined influence of gravity and radiation pressure force. We calculate cloud orbits under a large range of conditions and include the effect of a changing column density as a function of location. The dependence of radiation pressure force on the level of ionization and the column density are accurately computed. The main results are: a. The mean cloud location r(BLR) and the line widths (FWHMs) are combined in such a way that the simple virial mass estimate, r{BLR} FWHM^2/G, gives a reasonable approximation to the black hole mass M even when radiation pressure force is important. The reason is that L/M rather than L is the main parameter affecting the planar cloud motion. b. Reproducing the observed mean radius, FWHM and intensity of H-beta and CIV 1549 requires at least two different populations of clouds. c. The cloud location is a function of both L^{1/2} and L/M. Given this we suggest a new approximation for r(BLR) which, when inserted into the BH mass equation, results in a new approximation for M. The new expression involves L^{1/2}, FWHM and two constants that are obtained from a comparison with available M-sigma mass estimates. It deviates only slightly from the old mass estimate at all luminosities. d. The quality of present black hole mass estimators depends, critically, on the way the present M-sigma AGN sample (16 objects) represents the AGN population, in particular the distribution of Eddington ratios.