"Circularization" vs. Accretion -- What Powers Tidal Disruption Events?

Abstract

A tidal disruption event (TDE) takes place when a star passes near enough to a massive black hole to be disrupted. About half the star's matter is given elliptical trajectories with large apocenter distances, the other half is unbound. To "circularize", i.e., to form an accretion flow, the bound matter must lose a significant amount of energy, with the actual amount depending on the characteristic scale of the flow measured in units of the black hole's gravitational radius ( 1051 (R/1000Rg)-1~erg). Recent numerical simulations Shiokawa+2015 have revealed that the circularization scale is close to the scale of the most-bound initial orbits, 103 MBH,6.5-2/3 Rg 1015 MBH,6.51/3~cm from the black hole, and the corresponding circularization energy dissipation rate is 1044 MBH,6.5-1/6~erg/s. We suggest that the energy liberated during circularization, rather then energy liberated by accretion onto the black hole, powers the observed optical TDE candidates. The observed rise times, luminosities, temperatures, emission radii, and line widths seen in these TDEs [e.g.][]Arcavi+2014 are all more readily explained in terms of heating associated with circularization than in terms of accretion.