Keywords :
Galaxies: active; Galaxies: kinematics and dynamics; Methods: data analysis; Methods: numerical; Quasars: absorption lines; Radiation: dynamics; Black hole mass; Broad absorption lines; Galaxies active; Galaxies: Kinematics and dynamics; Metallicities; Method: numerical; Methods. Data analysis; Quasars absorption lines; Radiation dynamics; Theoretical modeling; Astronomy and Astrophysics; Space and Planetary Science; astro-ph.GA
Abstract :
[en] Context. We test the scenario according to which the broad absorption line (BAL) phenomenon in quasars (QSOs) is not a temporary stage of their life. In this scenario, the BAL effect acts only if the line of sight is within a spatially limited and collimated massive outflow cone covering only a fraction of the sky from the point of view of the nucleus. Aims. The aim is to understand the theoretical mechanism behind the massive outflow in BAL QSOs, which is important for modelling the impact of quasars on the star formation rate in the host galaxy, and, subsequently, on the galaxy evolution. Methods. We applied the specific theoretical model of dust-driven wind that was developed to explain broad emission lines. The model has considerable predictive power. The 2.5D version of the model called failed radiatively accelerated dusty outflow (FRADO) includes the formation of fast funnel-shaped outflow from the disk for a certain range of black hole masses, Eddington ratios, and metallicities. We now interpret BAL QSO as sources that are viewed along the outflowing stream. We calculated the probabilities of seeing the BAL phenomenon as functions of these global parameters, and we compared these probabilities to those seen in the observational data. We included considerations of the presence or absence of obscuring torus. Results. Comparing our theoretical results with observational data for a sample of QSOs consisting of two sub-populations of BAL and non-BAL QSOs, we found that in the model and in the data, the BAL phenomenon mostly occurs for sources with black hole masses higher than 108â Mâ . The effect increases with accretion rate, and high metallicities are also more likely in QSOs showing BAL features if a torus is taken into account. Conclusions. The consistency of the model with the data supports the interpretation of the BAL phenomenon as the result of the orientation of the source. It also supports the underlying theoretical model, although more consistency checks should be made in the future.
Funding text :
We thank the referee for the very helpful comments about the sample selection. The project was partially supported by the Polish Funding Agency National Science Centre, project 2017/26/A/ST9/00756 (MAESTRO 9), and MNiSW grant DIR/WK/2018/12. M.L.M.-A. acknowledges financial support from Millenium Nucleus NCN19_058 (TITANs). S.P. acknowledges the financial support from the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) Fellowship (164753/2020-6). M.H.N. acknowledges the financial support for this research on the basis of a grant awarded in the 2022 competition for young scientists by the Center for Theoretical Physics, Polish Academy of Sciences.
Commentary :
15 pages, 13 figures, 3 tables, Published in the Journal of Astronomy and Astrophysics (A&A)
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