Light WIMPs And Equivalent Neutrinos

Abstract

Very light WIMPs (chi), thermal relics that annihilate late in the early Universe, change the energy and entropy densities at BBN and at recombination. BBN, in combination with the CMB, can remove some of the degeneracies among light WIMPs and equivalent neutrinos, constraining the existence and properties of each. Depending on the nature of the light WIMP (Majorana or Dirac fermion, real or complex scalar) the joint BBN + CMB analyses set lower bounds to mchi in the range 0.5 - 5 MeV (mchi/me > 1 - 10), and they identify best fit values for mchi in the range 5 - 10 MeV. The joint BBN + CMB analysis finds a best fit value for the number of equivalent neutrinos, Delta Nnu ~ 0.65, nearly independent of the nature of the WIMP. In the absence of a light WIMP (mchi > 20 MeV), Neff = 3.05(1 + Delta Nnu /3). In this case, there is excellent agreement between BBN and the CMB, but the joint fit reveals Delta Nnu = 0.40+-0.17, disfavoring standard big bang nucleosynthesis (SBBN) (Delta Nnu = 0) at ~ 2.4 sigma, as well as a sterile neutrino (Delta Nnu = 1) at ~ 3.5 sigma. The best BBN + CMB joint fit disfavors the absence of dark radiation (Delta Nnu = 0 at ~ 95% confidence), while allowing for the presence of a sterile neutrino (Delta Nnu = 1 at ~ 1 sigma). For all cases considered here, the lithium problem persists. These results, presented at the TAUP 2013 Conference, are based on Nollett & Steigman (2013).