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Light Curves of Tidal Disruption Events in Active Galactic Nuclei

Chi-Ho Chan, Tsvi Piran, Julian H. Krolik

2020The Astrophysical Journal27 citationsDOIOpen Access PDF

Abstract

Abstract The black hole of an active galactic nucleus is encircled by an accretion disk. The surface density of the disk is always too low to affect the tidal disruption of a star, but it can be high enough that a vigorous interaction results when the debris stream returns to pericenter and punches through the disk. Shocks excited in the disk dissipate the kinetic energy of the disk interior to the impact point and expedite inflow toward the black hole. Radiatively efficient disks with luminosity Eddington have a high enough surface density that the initial stream–disk interaction leads to energy dissipation at a super-Eddington rate. Because of the rapid inflow, only part of this dissipated energy emerges as radiation, while the rest is advected into the black hole. Dissipation, inflow, and cooling balance to keep the bolometric luminosity at an Eddington-level plateau whose duration is tens of days, with an almost linear dependence on stellar mass. After the plateau, the luminosity decreases in proportion to the disk surface density, with a power-law index between −3 and −2 at earlier times, and possibly a steeper index at later times.

Topics & Concepts

PhysicsAstrophysicsActive galactic nucleusLuminosityAccretion (finance)DissipationAstronomyBlack hole (networking)Light curveKinetic energyAccretion discEddington luminosityPlateau (mathematics)Supermassive black holeRADIUSTidal heatingOrbital eccentricityDoppler effectRadiation pressureLine (geometry)DebrisTidal forceAstrophysical Phenomena and ObservationsAstrophysics and Star Formation StudiesAstronomy and Astrophysical Research
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