Early Dark Energy During Big Bang Nucleosynthesis
Abstract
We study the impact of an early dark energy component (EDE) present during big bang nucleosynthesis (BBN) on the elemental abundances of deuterium D/H, and helium Yp, as well as the effective relativistic degrees of freedom N eff. We consider a simple model of EDE that is constant up to a critical time. After this critical time, the EDE transitions into either a radiation component that interacts with the electromagnetic plasma, a dark radiation component that is uncoupled from the plasma, or kination that is also uncoupled. We use measured values of the abundances and N eff as determined by CMB observations to establish limits on the input parameters of this EDE model. In addition, we explore how those parameters are correlated with BBN inputs; the baryon to photon ratio ηb, neutron lifetime τn, and number of neutrinos N. Finally, we study whether this setup can alleviate the tension introduced by recent measurements of the primordial helium abundance.
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