Consistent N eff fitting in big bang nucleosynthesis analysis

Abstract

The effective number of neutrino species, N eff, serves as a key fitting parameter extensively employed in cosmological studies. In this work, we point out a fundamental inconsistency in the conventional treatment of N eff in big bang nucleosynthesis (BBN), particularly regarding its applicability to new physics scenarios where N eff, the deviation of N eff from the standard BBN prediction, is negative. To ensure consistent interpretation, it is imperative to either restrict the allowed range of N eff or systematically adjust neutrino-induced reaction rates based on physically motivated assumptions. As a concrete example, we consider a simple scenario in which a negative N eff arises from entropy injection into the electromagnetic sector due to the decay of long-lived particles after neutrino decoupling. This process dilutes the neutrino density and suppresses the rate of neutrino-driven neutron-proton conversion. Under this assumption, we demonstrate that the resulting BBN constraints on N eff deviate significantly from those obtained by the conventional, but unphysical, extrapolation of dark radiation scenarios into the N eff < 0 regime.