The effect of relativistic precession on light curves of tidal disruption events

The disruption of a star by the tidal forces of a spinning black hole causes the stellar stream to precess, which affects the conditions for triggering the tidal disruption event (TDE). In this work, we study the effect of the precession of the tidal stream on TDE light curves, as a result of the interaction of the wind and luminosity of the event with the stellar stream wrapped around the black hole. We perform two-dimensional radiation-hydrodynamic simulations using the moving-mesh hydrodynamic code JET with its recently developed radiation treatment module. The model considers an isotropic wind and irradiation following the analytical fallback rate of a stellar polytrope, and their interaction with the remnant of the precessed stream. We study the effect of the black hole mass, the accretion efficiency, and the inclination between the orbital and spin planes on the observed light curves along different lines of sight. From our results, we were able to identify two extreme behaviours depending on the properties of the event: i) models with low-mass black holes ($\sim10^6~M_{\odot}$), low inclination ($\sim0$), and low accretion efficiency ($\sim0.01$) show light curves with a short early peak caused by the interaction of the wind with the inner edge of the stream. The line of sight has little effect on the light curves, since the stream covers only a small fraction of the solid angle, due to the precession occurring in the orbital plane; ii) models with high-mass black holes ($>10^7~M_{\odot}$), high inclination ($\sim90^{\circ}$), and high accretion efficiency ($\sim0.1$) produce light curves with luminosity peaks that can be delayed by up to 50-100~d as the stream blocks the radiation in the early phase of the event. Our results show that black hole spin and misalignment do not imprint a recognisable feature on the light curves but rather can add complications to their analysis.