Insights into Tidal Disruption of Stars from PS1-10jh

TL;DR

This paper analyzes the tidal disruption event PS1-10jh, concluding it involved a helium core star disrupted by a low-mass black hole, with insights into the energetics, outflow dynamics, and implications for super-Eddington accretion.

Contribution

It provides spectroscopic and photometric evidence that PS1-10jh was a helium core disruption, offering new insights into the energetics and outflow mechanisms of tidal disruption events.

Findings

Disrupted a helium core star, not a solar-type star.

Inferred outflow of ~0.01 solar masses at ~1000 km/s.

Estimated radiated energy of ~2 x 10^{51} erg.

Abstract

Was PS1-10jh (Gezari et al. 2012), an optical/UV transient discovered by the Pan-STARRS Medium Deep Survey, the tidal disruption of a star by a massive black hole? We address two aspects of the problem: the composition of the putative disrupted object (using the spectroscopic data), and the energetics of the observed gas and radiation (using the photometric data). We perform photoionization calculations and compare with the observed lower limit of the line ratio L(He II 4686)/L(Halpha) > 5 to argue that this event was not the disruption of a solar-type star, and instead was likely the disruption of a helium core (as first proposed by Gezari et al. 2012). Disruption of such a dense object requires a relatively small central BH, M_BH <~ 2 x 10^5 M_sun. We use the photometric data to infer that PS1-10jh comprised an outflow of ~ 0.01 M_sun of gas, escaping from the BH at ~1000 km/s, and we propose that this outflow was driven primarily by radiation pressure trapped by Thomson and resonance line scattering. The large ratio of radiated energy to kinetic energy, E_rad/E_K ~ 10^4, together with the large value of E_rad ~ 2 x 10^(51) erg, suggests that the outflow was shocked at large radius (perhaps similar to super-luminous supernovae or the internal shock model for gamma-ray bursts). We describe puzzles in the physics of PS1-10jh, and discuss how this event may help us understand future tidal disruptions and super-Eddington accretion events as well.