Abstract
(Abridged) We investigate the observational characteristics of BLR geometries in which the BLR clouds bridge the gap, both in distance and scale height, between the outer accretion disc and the hot dust, forming an effective surface of a "bowl". The gas dynamics are dominated by gravity, and we include the effects of transverse Doppler shift, gravitational redshift and scale-height dependent macro-turbulence. Our simple model reproduces many of the phenomena observed in broad emission-line variability studies, including (i) the absence of response in the core of the optical recombination lines on short timescales, (ii) the enhanced red-wing response on short timescales, (iii) differences between the measured delays for the HILs and LILs, and (iv) identifies turbulence as a means of producing Lorentzian profiles (esp. for LILs) in low inclination systems, and for suppressing significant continuum--emission-line delays between the line wings and line core (esp. in LILs). A key motivation of this work was to reveal the physical underpinnings of the reported measurements of SMBH masses and their uncertainties. We find that SMBH masses derived from measurements of the fwhm of the mean and rms profiles show the closest correspondence between the emission lines in a single object, even though the emission line fwhm is a more biased mass indicator with respect to inclination. The predicted large discrepancies in the SMBH mass estimates between emission lines at low inclination, as derived using the line dispersion, we suggest may be used as a means of identifying near face-on systems. Our general results do not depend on specific choices in the simplifying assumptions, but are in fact generic properties of BLR geometries with axial symmetry that span a substantial range in radially-increasing scale height supported by turbulence, which then merge into the inner dusty TOR.
Highlights
Intensive multiwavelength monitoring campaigns of a handful of individual active galactic nuclei (AGN) have radically altered our view of the broad emission-line region
Rather we aim to explore the observational consequences of assuming a bowl-shaped broad emission line region (BLR) geometry in which the gas dynamics are dominated by the central supermassive black hole, and how these impact on our interpretation of line profile shapes, correlated continuum and emission-line variability, velocity resolved response functions, black hole mass estimates and virial scale factors reported in the literature for both individual sources and among the AGN population as a whole
We aim to reveal the relationship between the physical properties of our model and the measured quantities used in black hole mass determinations
Summary
Intensive multiwavelength monitoring campaigns of a handful of individual active galactic nuclei (AGN) have radically altered our view of the broad emission-line region (hereafter BLR). The gas dynamics are largely dominated by the central supermassive black hole, a realization which when coupled with estimates of the BLR size and gas velocity dispersion has enabled the determination of virial black hole masses in ≈40 nearby AGN (Peterson 2010). The derived (geometry dependent) virial scale factors appear approximately constant amongst the emission lines in individual sources, and over many seasons for which the mean source luminosity can differ considerably (see Krolik et al 1991; Peterson & Wandel 1999, 2000; Kollatschny 2003a; Peterson et al 2004; Bentz et al 2007; Denney et al 2010; Peterson 2010, and references therein), consistent with a virialized velocity field within an ionization stratified BLR. Initial attempts were limited to determining the ‘time-averaged response’
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