Constraining Early Dark Energy cosmological models with Big Bang Nucleosynthesis

Abstract

The recent cosmological picture contains a significant tension indicating that our standard ΛCDM picture may be incomplete. Early Dark Energy models can alleviate the Hubble tension, by assuming an early acceleration that could explain the divergence between the early and late-time cosmological data. We investigate the implications of Early Dark Energy models on the Big Bang Nucleosynthesis processes by considering several cosmological models, including a model assuming a simple cosmological constant, alongside with varying equations of state dark energy models. We construct a simulator through a nested sampling algorithm, with the help of which we estimate the upper bounds for model parameters, and determine the maximum allowable dark energy density contribution during the radiation-dominated era. Our results are obtained through the https://github.com/croi900/edeneden program. We show that for a linear or polytropic equation of state, the dark energy density is constrained to less than 10-13 MeV4 and 10-5 MeV4, respectively, at the 95\% confidence level. Furthermore, we identify a temperature-dependent equation of state of dark energy as the most physically compelling framework, which remains consistent with primordial abundances for coupling parameters 10-2. This model successfully allows for high-temperature deviations from the standard ΛCDM expansion history, while rapidly diluting to obtain standard general relativistic results in the weak freeze-out era.