First star formation in extremely early epochs

Abstract

First stars play crucial roles in development of the universe, influencing events like cosmic reionization and the chemical enrichment. While first stars are conventionally thought to form at around z 20-30 in the standard Cold Dark Matter () cosmology, observational constraints on small-scale density fluctuations remain limited, possibly differing significantly from the scale-invariant fluctuations assumed in the model. Should this be the case, the formation of first stars could occur much earlier than typically predicted. In this study, we investigate the formation process of first stars in the extremely early epochs of z 100 in the post-recombination universe. At such early times, the effects of the warm cosmic microwave background (CMB) become significant. We calculate the collapse of primordial star-forming clouds using a one-zone thermo-chemical model that accounts for CMB influences on radiative heating, Compton cooling, and photodissociation reactions. We found that the impact of the CMB on the evolution is limited at z 100, with the temperature evolution closely resembling the conventional model. However, within the range 100 z 400, the formation of H2 via the H- channel is impeded by H- photodetachment induced by the CMB, leading to higher temperatures compared to standard one. Consequently, first stars with masses exceeding 1000 ~M can emerge at z 100. Furthermore, at z 500, the temperature evolution becomes nearly isothermal solely due to atomic cooling, as H2 formation is entirely suppressed. In such cases, supermassive stars with masses around 105 ~M are expected to form solely via atomic cooling. These findings emphasize the significant variation in the typical mass of the first stars depending on the epoch of formation.

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