Tidal disruptions of main sequence stars -- IV. Relativistic effects and dependence on black hole mass

Abstract

Using a suite of fully relativistic hydrodynamic simulations applied to main-sequence stars with realistic internal density profiles, we examine full and partial tidal disruptions across a wide range of black hole mass (105≤ M BH/M≤ 5× 107) and stellar mass (0.3 ≤ M /M≤ 3) as larger M BH leads to stronger relativistic effects. For fixed M, as M BH increases, the ratio of the maximum pericenter distance yielding full disruptions (R t) to its Newtonian prediction rises rapidly, becoming triple the Newtonian value for M BH = 5×107~ M, while the ratio of the energy width of the stellar debris for full disruptions to the Newtonian prediction decreases steeply, resulting in a factor of two correction at M BH = 5 × 107~ M. We find that for partial disruptions, the fractional remnant mass for a given ratio of the pericenter to R t is higher for larger M BH. These results have several implications. As M BH increases above 107~ M, the cross section for complete disruptions is suppressed by competition with direct capture. However, the cross section ratio for partial to complete disruptions depends only weakly on M BH. The relativistic correction to the debris energy width delays the time of peak mass-return rate and diminishes the magnitude of the peak return rate. For M BH 107~ M, the M BH-dependence of the full disruption cross section and the peak mass-return rate and time is influenced more by relativistic effects than by Newtonian dynamics.