Baryon-dark matter scattering and first star formation

TL;DR

This study investigates how baryon-dark matter scattering influences the formation of the first stars, suggesting certain dark matter properties are incompatible with early star formation, based on 21-cm cosmological observations.

Contribution

It introduces a one-zone model to analyze the impact of baryon-dark matter scattering on primordial star formation, linking dark matter properties with early cosmic evolution.

Findings

Massive Pop III stars form more readily with certain dark matter parameters.

Some dark matter models are excluded due to inability to produce early massive stars.

Constraints from star formation physics align with 21-cm observational inferences.

Abstract

The recent detection of the sky-averaged 21-cm cosmological signal indicates a stronger absorption than the maximum allowed value based on the standard model. One explanation for the required colder primordial gas is the energy transfer between the baryon and dark matter fluids due to non-gravitational scattering. Here, we explore the thermal evolution of primordial gas, collapsing to form Population III (Pop III) stars, when this energy transfer is included. Performing a series of one-zone calculations, we find that the evolution results in stars more massive than in the standard model, provided that the dark matter is described by the best-fit parameters inferred from the 21-cm observation. On the other hand, a significant part of the dark matter parameter space can be excluded by the requirement to form massive Pop III stars sufficiently early in cosmic history. Otherwise, the radiation background needed to bring about the strong Wouthuysen-Field coupling at z >~ 17, inferred to explain the 21-cm absorption feature, could not be builtup. Intriguingly, the independent constraint from the physics of first star formation at high densities points to a similarly narrow range in dark matter properties. This exploratory study has to be followed-up with self-consistent three-dimensional simulations for a more rigorous derivation.