Red giant - jet collisions in galactic nuclei I: 3D hydrodynamical model of a few stellar orbits

Abstract

Several models have been proposed to explain missing red giants (RGs) near the Galactic centre. Recently, a scenario has been suggested that predicts, among other processes, a long-term ablation of the surface layers of RGs during their repetitive passages through the Galactic jet (Zajacek et al., 2020). In this study, we perform detailed three-dimensional numerical modelling of this phenomenon. We calculate the ablation rate of the surface layers of a RG orbiting the supermassive black hole (SMBH) as it passes through the nuclear jet. In particular, we model the jet-star interaction for approximately 10 passages for the closer orbital distance of 10-3\,pc and 2 passages for 10-2\,pc. We find that the mass loss due to ablation by the jet behaves with time as M t and the total ablated mass during a single active galactic nucleus (AGN) phase (105 years) is 10-4\,M. We arrive at similar rates of the stellar ablation for the relatively smaller jet luminosity 1042\,erg\,s-1 as in the previous analytical calculations. For larger jet luminosities of 1044 and 1048\,erg\,s-1, the ablation rates inferred from 10 interactions as well as extrapolated power-law fits are significantly lower than analytical values. Overall, the mass ablation rate per interaction and the extrapolated cumulative mass loss during the jet activity are comparable to the stellar-wind mass loss. For the smallest orbital distance of 10-3\,pc, we also track the thermal behaviour of the stellar surface layer, whose temperature appears to grow rapidly during the first 10 passages from 3600\, K (spectral type M) to 8500\, K (spectral type A). RG-jet interactions can thus lead to observable changes in the nuclear stellar population during the jet existence.