BBN And The CMB Constrain Light, Electromagnetically Coupled WIMPs

Abstract

(Abridged) In the presence of a light WIMP (< 30 MeV), there are degeneracies among the nature of the WIMP, its couplings to standard model particles, its mass mchi, and the number of equivalent neutrinos beyond the standard model, Delta Nnu. These degeneracies cannot be broken by the CMB constraint on the effective number of neutrinos, Neff. However, big bang nucleosynthesis (BBN) is affected by a light WIMP and equivalent neutrinos, so the combination of BBN and CMB can break some of the degeneracies. Here, BBN predictions for abundances in the presence of a light WIMP and equivalent neutrinos are explored, and estimates of their observationally determined relic abundances are used to limit mchi, Delta Nnu, and the present Universe baryon density (OmegaB h2). These constraints are explored for Majorana and Dirac fermion WIMPs, as well as for real and complex scalar WIMPs that couple to electrons, positrons, and photons. In a separate paper this analysis is repeated for WIMPs that couple only to the standard model neutrinos, and constraints for the two cases are contrasted. Without a light WIMP but allowing for equivalent neutrinos, the combined BBN and CMB constraints favor Neff = 3.46 +/- 0.17, OmegaB h2 = 0.0224 +/- 0.0003, and Delta Nnu = 0.40 +/- 0.17. In this case, standard BBN (Delta Nnu = 0) is disfavored at ~98% confidence, and the presence of one sterile neutrino (Delta Nnu = 1) is disfavored at > 99% confidence. Allowing a light WIMP and Delta Nnu equivalent neutrinos together, the combined BBN and CMB data provide lower limits to the WIMP masses (> 0.5 - 5 MeV) that depend on the nature of the WIMP, favor mchi ~8 MeV slightly over no WIMP, and loosen constraints on equivalent neutrinos, Delta Nnu = 0.65+0.46-0.35. While Delta Nnu = 0 is still disfavored at ~95% confidence with a light WIMP, Delta Nnu = 1 is now allowed.