Abstract
Light, weakly-coupled dark sectors may be naturally decoupled in the early universe and enter equilibrium with the Standard Model bath during the epoch of primordial nucleosynthesis. The equilibration and eventual decoupling of dark sector states modifies the expansion rate of the universe, which alters the predicted abundances of the light elements. This effect can be encompassed in a time-varying contribution to $N_{\mathrm{eff}}$, the effective number of neutrino species, such that $N_{\mathrm{eff}}$ during nucleosynthesis differs from its measured value at the time of recombination. We investigate the impact of such variations on the light element abundances with model-independent templates for the time-dependence of $N_{\mathrm{eff}}$ as well as in specific models where a dark sector equilibrates with neutrinos or photons. We find that significant modifications of the expansion rate are consistent with the measured abundances of light nuclei, provided that they occur during specific periods of nucleosynthesis. In constraining concrete models, the relative importance of the cosmic microwave background and primordial nucleosynthesis is highly model-dependent.
Highlights
Measurements of the light element abundances provide one of the earliest direct tests of cosmology
III, we reviewed how the expansion rate (Neff) and the baryonic density control the outcome of primordial nucleosynthesis and how time-independent deviations of these quantities away from their Standard Model (SM) expectations lead to changes in the predicted abundances of helium-4 and deuterium
The concordance of the predictions of standard big bang nucleosynthesis with observations of 4He and D abundances constrains the existence of new physics that contributes significantly to the energy density of the Universe at that time
Summary
Measurements of the light element abundances provide one of the earliest direct tests of cosmology. If equilibration takes place after neutrino-photon decoupling, the resulting modification to the expansion rate is suppressed [19,20,22,23], allowing for the presence of many new degrees of freedom at the SM temperature. The equilibration of a light dark sector (DS) with one of these two SM components has a distinct impact on the effective number of neutrino species, Neff, which parametrizes the energy density of the primordial plasma in nonelectromagnetic degrees of freedom. There, we discuss our numerical methods and treatment of nuclear rate uncertainties We use this framework to first study the impact of time-dependent modifications to Neff in a.
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