📝 SummarXiv

Abstract

The high densities in the early Universe provide a unique laboratory to constrain couplings between feebly interacting particles, such as dark matter and neutrinos. In this article, we study how Big Bang Nucleosynthesis can constrain models of Ultra-Light Dark Matter diagonally coupled to neutrinos. We follow an adiabatic formalism which allows to average-out the rapid oscillations of the Dark Matter field and consistently take into account the feedback between the neutrino and the Dark Matter fields. This feedback alters the early Universe dynamics, causing the Dark Matter energy density to scale as radiation, while the neutrino mass scales as $a^{-1}$. These two effects modify primordial element abundances by modifying interaction rates and the expansion rate during nucleosynthesis. Then, we use primordial abundances to obtain leading cosmological bounds on the coupling in the range $m_\phi/{\rm eV}\in (10^{-22},10^{-17})$, namely $g\lesssim 0.13(m_\phi/{\rm eV})$ for $m_\phi \gtrsim 3\times 10^{-20}\,\rm eV$ and $g\lesssim 1.8\times 10^{-11}\sqrt{m_\phi/\rm eV}$ for $m_\phi \lesssim 3\times 10^{-20}\,\rm eV$. This consistent cosmological treatment emphasizes that, in the mass interval where its physical assumptions hold, neutrino masses cannot be generated refractively by a direct coupling with an Ultra-Light Dark Matter field.