Abstract
Can high ionization lines such as CIV λ 1549 provide useful virial broadening estimators for computing the mass of the supermassive black holes that power the quasar phenomenon? The question has been dismissed by several workers as a rhetorical one because blue-shifted, non-virial emission associated with gas outflows is often prominent in CIV λ 1549 line profiles. In this contribution, we first summarize the evidence suggesting that the FWHM of low-ionization lines like H β and MgII λ 2800 provide reliable virial broadening estimators over a broad range of luminosity. We confirm that the line widths of CIV λ 1549 is not immediately offering a virial broadening estimator equivalent to the width of low-ionization lines. However, capitalizing on the results of Coatman et al. (2016) and Sulentic et al. (2017), we suggest a correction to FWHM CIV λ 1549 for Eddington ratio and luminosity effects that, however, remains cumbersome to apply in practice. Intermediate ionization lines (IP ∼ 20–30 eV; AlIII λ 1860 and SiIII] λ 1892) may provide a better virial broadening estimator for high redshift quasars, but larger samples are needed to assess their reliability. Ultimately, they may be associated with the broad-line region radius estimated from the photoionization method introduced by Negrete et al. (2013) to obtain black hole mass estimates independent from scaling laws.
Highlights
Statement of the ProblemA defining property of type-1 quasars is the presence of broad and narrow optical and UV lines emitted by ionic species over a wide range of ionization potentials (IPs, [1]): high-ionization lines (HILs) involving IP > 50 eV, and low-ionization lines (LILs) from ionic species with IP < 20 eV.Over the years, it has turned expedient to consider the UV resonance line CIVλ1549 as a representative of broad HILs
We briefly stress the importance of black hole mass estimates (Section 2) and recapitulate the basic method of MBH estimates applied to large samples of quasars under the virial assumption (Section 3)
Our analysis is focused on virial broadening estimators (VBEs; Section 5) from: (a) LILs (IP < 15 eV: Hβ, MgII 2800); (b) HILs (IP > 40 eV: CIVλ1549); (c) intermediate-ionization lines (IILs: SiIII]λ1892, Al IIIλ1860), for which we provide a brief summary of preliminary results
Summary
A defining property of type-1 quasars is the presence of broad and narrow optical and UV lines emitted by ionic species over a wide range of ionization potentials (IPs, [1]): high-ionization lines (HILs) involving IP > 50 eV, and low-ionization lines (LILs) from ionic species with IP < 20 eV. The occurrence of CIVλ1549 large shifts constrains the suitability of the CIVλ1549 profile broadening as a virial black hole mass (MBH ) estimator (see, e.g., [4,5], for reviews). Results at low-redshift obtained in the mid-2010s suggest that the CIVλ1549 line is unsuitable for, at least, part of the quasar Population. In this contribution, we briefly stress the importance of black hole mass estimates (Section 2) and recapitulate the basic method of MBH estimates applied to large samples of quasars under the virial assumption (Section 3). Our analysis is focused on virial broadening estimators (VBEs; Section 5) from: (a) LILs (IP < 15 eV: Hβ, MgII 2800); (b) HILs (IP > 40 eV: CIVλ1549);. We suggest that “photoioionization” computations of MBH (Section 6) may offer a solution to some of the problems associated with the use of an average scaling law
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
