General limit on the relation between abundances of D and 7Li in big bang nucleosynthesis with nucleon injections

Abstract

The injections of energetic hadrons could have occurred in the early universe by decays of hypothetical long-lived exotic particles. The injections induce the showers of nonthermal hadrons via nuclear scattering. Neutrons generated at these events can react with 7Be nuclei and reduce 7Be abundance solving a problem of the primordial 7Li abundance. We suggest that thermal neutron injection is a way to derive a model independent conservative limit on the relation between abundances of D and 7Li in a hadronic energy injection model. We emphasize that an uncertainty in cross sections of inelastic n+p scattering affects the total number of induced neutrons, which determines final abundances of D and 7Li. In addition, the annihilations of antinucleons with 4He result in higher D abundance and trigger nonthermal 6Li production. It is concluded that a reduction of 7Li abundance from a value in the standard big bang nucleosynthesis (BBN) model down to an observational two σ upper limit is necessarily accompanied by an undesirable increase of D abundance up to at least an observational 12 σ upper limit from observations of quasi-stellar object absorption line systems. The effects of antinucleons and secondary particles produced in the hadronic showers always lead to a severer constraint. The BBN models involving any injections of extra neutrons are thus unlikely to reproduce a small 7Li abundance consistent with observations.