SIMPonium bound states of complex scalar dark matter: Relic density and astrophysical signatures

Abstract

We study a strongly interacting complex scalar dark matter candidate (), subject to an attractive potential mediated by a vector boson Aμ. Such interactions allow to form bound states: SIMPonium. In this work, we systematically investigate the bound state dynamics of our dark sector, including the formation and decay of SIMPonium and it's influence on the thermal history. Our analysis shows in absence of any bound state formation freezes out at x≈ 16 and the presence of SIMPonium in the thermal bath slightly modifies the freeze out behaviour of the free particles, which freezes out at x ≈ 20. While the bound state itself remains in chemical equilibrium for a longer duration and freezes out at a significantly later time, x ≈ 250. We compute the indirect energy spectra arising from free dark matter annihilation and SIMPonium decay, where the resulting Standard Model particles subsequently produce both final state radiation and radiative decay spectra. We find that the total differential photon flux from dark matter with mass m = 150\,MeV lies in the range Eγ2 dφd\, dEγ ∈ [10-27,\,10-17] \,MeV\,cm-2\,s-1\,sr-1 , for photon energies in the interval Eγ ∈ [10-3,\,102] \,MeV. The predicted signal is therefore exceedingly feeble and remains well below the sensitivity of current experimental facilities.