The Growth of the Central Black Holes in Quasi-stars
Abstract
Observations by JWST have confirmed the presence of supermassive black holes (BHs) at redshifts z10, lending support to scenarios in which BHs experience rapid growth through intense gas accretion. Here we investigate the growth of a BH embedded at the center of a quasi-star, a theoretically predicted object formed via direct collapse. In a quasi-star, the central BH accretes at a highly super-Eddington rate, while the excess energy is transported outward by convection and radiated at approximately the Eddington luminosity of the entire star. We employ the open-source stellar evolution code MESA to construct quasi-star models and follow the time-dependent growth of the central BH under different prescriptions for the accretion rate at the inner boundary Ri, and further considering the effect of winds. For the case Ri=NR B, where N is a constant and R B is the Bondi radius corresponding to the mass of the BH and the gas infalling onto it, our models terminate when the BH mass reaches a critical value Mcrit(N)=cs,i3/(12N3G3πi) (where cs,i and i are the sound speed and density at Ri, respectively), a limit we also derive analytically. Models that feature an inner convective region matched to an outer adiabatic envelope exhibit BH growth up to approximately MBH/M 0.33, largely independent of the stellar mass M itself. This ratio is approximately preserved even in the presence of mass loss, as several properties of the model are independent of the quasi-star's total mass.
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