The Sloan Digital Sky Survey Reverberation Mapping Project: Accretion and Broad Emission Line Physics from a Hypervariable Quasar

The Sloan Digital Sky Survey Reverberation Mapping Project: Accretion and Broad Emission Line Physics from a Hypervariable QuasarDexter, JasonXin, ShuoShen, YueGrier, C. J.Liu, TengGezari, SuviMcGreer, Ian D.Brandt, W. N.Hall, P. B.Horne, KeithSimm, TorbenMerloni, AndreaGreen, Paul J.Vivek, M.Trump, Jonathan R.Homayouni, YasamanPeterson, B. M.Schneider, Donald P.Kinemuchi, K.Pan, KaikeBizyaev, DmitryDOI: info:10.3847/1538-4357/ab4354v. 88544
Dexter, Jason, Xin, Shuo, Shen, Yue, Grier, C. J., Liu, Teng, Gezari, Suvi, McGreer, Ian D., Brandt, W. N., Hall, P. B., Horne, Keith, Simm, Torben, Merloni, Andrea, Green, Paul J., Vivek, M., Trump, Jonathan R., Homayouni, Yasaman, Peterson, B. M., Schneider, Donald P., Kinemuchi, K., Pan, Kaike, and Bizyaev, Dmitry. 2019. "The Sloan Digital Sky Survey Reverberation Mapping Project: Accretion and Broad Emission Line Physics from a Hypervariable Quasar." The Astrophysical Journal 885:44. https://doi.org/10.3847/1538-4357/ab4354
ID: 154605
Type: article
Authors: Dexter, Jason; Xin, Shuo; Shen, Yue; Grier, C. J.; Liu, Teng; Gezari, Suvi; McGreer, Ian D.; Brandt, W. N.; Hall, P. B.; Horne, Keith; Simm, Torben; Merloni, Andrea; Green, Paul J.; Vivek, M.; Trump, Jonathan R.; Homayouni, Yasaman; Peterson, B. M.; Schneider, Donald P.; Kinemuchi, K.; Pan, Kaike; Bizyaev, Dmitry
Abstract: We analyze extensive spectroscopic and photometric data of the hypervariable quasar SDSS J141324+530527 (RMID 017) at z = 0.456, an optical "changing-look" quasar from the Sloan Digital Sky Survey Reverberation Mapping project that increased in optical luminosity by a factor ≃10 between 2014 and 2017. The observed broad emission lines all respond in luminosity and width to the changing optical continuum, as expected for photoionization in a stratified, virialized broad emission line region. The luminosity changes therefore result from intrinsic changes in accretion power rather than variable obscuration. The variability is continuous and apparently stochastic, disfavoring an origin as a discrete event such as a tidal disruption flare or microlensing event. It is coordinated on day timescales with blue leading red, consistent with reprocessing powering the entire optical spectral energy distribution. We show that this process cannot work in a standard thin disk geometry on energetic grounds, and would instead require a large covering factor reprocessor. Disk instability models could potentially also explain the data, provided that the instability sets in near the inner radius of a geometrically thick accretion disk.