The case for mixed dark matter from sterile neutrinos

TL;DR

This paper investigates the production of heavy sterile neutrinos in the early universe, exploring their potential as mixed dark matter candidates through detailed kinetic modeling and finite temperature effects.

Contribution

It introduces a comprehensive kinetic framework for sterile neutrino production, including finite temperature effects and pion decay processes, to evaluate their viability as dark matter.

Findings

Heavy neutrinos can be produced via pion decay with finite temperature corrections.

Frozen distributions show effects of kinematic entanglement, affecting dark matter viability.

Heavy neutrinos with long lifetimes may freeze out as dark matter candidates.

Abstract

Sterile neutrinos are SU(2) singlets that mix with active neutrinos via a mass matrix, its diagonalization leads to mass eigenstates that couple via standard model vertices. We study the cosmological production of heavy neutrinos via standard model charged and neutral current vertices under a minimal set of assumptions: i) the mass basis contains a hierarchy of heavy neutrinos, ii) these have very small mixing angles with the active (flavor) neutrinos, iii) standard model particles, including light (active-like) neutrinos are in thermal equilibrium. The same weak interaction processes that produce active-like neutrinos also produce the heavier species. We introduce the kinetic equations that describe their production, freeze out and decay and discuss the various processes that lead to their production in a wide range of temperatures assessing their feasibility as dark matter candidates. We identify processes in which finite temperature collective excitations lead to the production of the heavy species. As a specific example, we consider the production of heavy neutrinos from pion decay shortly after the QCD crossover including finite temperature corrections to the pion form factors and mass. We consider the different decay channels that allow for the production of heavy neutrinos showing that their frozen distribution functions exhibit effects from "kinematic entanglement" and argue for their viability as mixed dark matter candidates. We discuss abundance, phase space density and stability constraints and argue that heavy neutrinos with lifetime $\tau> 1/H_0$ freeze out of local thermal equilibrium, and \emph{conjecture} that those with lifetimes $\tau \ll 1/H_0$ may undergo cascade decay into lighter DM candidates and/or inject non-LTE neutrinos into the cosmic neutrino background. We provide a comparison with non-resonant production via active-sterile mixing.