Underluminous tidal disruptions

We have evidence of X-ray flares in several galaxies consistent with a a star being tidally disrupted by a supermassive black hole (MBH). If the star starts on a nearly parabolic orbit relative to the MBH, one can derive that the fallback rate follows a $t^{-5/3}$ decay in the bolometric luminosity. We have modified the standard version of the smoothed-particle hydrodynamics (SPH) code {\sc Gadget} to include a relativistic treatment of the gravitational forces. We include non-spinning post-Newtonian corrections to incorpore the periapsis shift and the spin-orbit coupling up to next-to-lowest order. We run a set of simulations for different penetration factors in both the Newtonian- and the relativistic regime. We find that tidal disruptions around MBHs in the relativistic cases are underluminous for values starting at $\beta \gtrapprox 2.25$; i.e. the fallback curves produced in the relativistic cases are progressively lower compared to the Newtonian simulations as the penetration parameter increases. This is due to the fact that, contrary to the Newtonian cases, we find that all relativistic counterparts feature a survival core for penetration factors going to values as high as $12.05$. We derive a relativistic calculation which shows that geodesics of the elements in the star converge as compared to the Newtonian case, allowing for a core to survive the tidal disruption. A survival core should consistently emerge from any TDE with $\beta \gtrapprox 2.25$. The higher the value, the lower the colour temperatures than derived from standard accretion models.