A quasi-star is born: formation and evolution of accreting quasi-stars as a metallicity-independent pathway to Little Red Dots
Abstract
To investigate the rest-frame optical emission of "Little Red Dots", we model the formation of and evolution of quasi-stars, i.e. stellar envelopes supported by the accretion luminosity onto a central black hole, originating from rapidly accreting proto-stars reaching the supermassive star regime (>104 M) and undergoing general relativistic instability. We compute stellar evolution models with net mass gain rates =0.01, 0.1, and 1 M/yr and metallicities Z=0-0.01. For the mass gain rates 0.1 M/yr, stars remain nearly fully convective with Teff4000-9000~K. The general relativistic instability leading to central BH formation occurs at M3.5×104 M (6.6×104 M) for M acc=0.1 M/yr (1 M/yr), at luminosities L 109 L. The lifetime of quasi-stars is estimated to be 107-108~yr, 100-1000 times longer than their progenitors. In an environment allowing for rapid accretion the formation, evolution, and properties of quasi-stars are found be essentially independent of metallicity. Comparing the luminosities of our models with those of Little Red Dots at z<4.5 (Lbol109.5-1011.5 L) yields quasi-star masses 104.5-106.5 M. The observed minimum luminosity of 109.5~\ implies accretion rates 0.1 M/yr for Little Red Dots progenitors. Our models offer a metallicity-independent framework supporting quasi-stars as the source of Little Red Dot optical emission, and provide insights into their lifetimes, composition, and progenitor environment.
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