Production of matter in the universe via after-GUT interaction

Abstract

In this paper we propose a model of production of ordinary and dark matter in the decay of a hypothetical antigravitating medium in the form of a condensate of (zero-momentum) spinless massive particles (denoted as φ) which fills the universe. The decays of φ-particles into baryons, leptons, and dark matter particles are caused by some (after-GUT) interaction with the mass scale between the electroweak and grand unification. The observed dark energy is identified with a portion of a condensate which has not decayed up to the instant of measurement. The decay rate of φ-particles φ is expressed through the three parameters - the coupling constant αX, the mass scale MX which defines the mass of X-particle as the mediator of after-GUT interaction, and the energy imparted to the decay products. We show that the masses of dark matter particle m≈ 5 GeV and φ-particle mφ≈ 15 GeV can be extracted from the 7-year WMAP and other astrophysical data about the contributions of baryon, dark matter, and dark energy densities to the total matter-energy density budget in our universe. Such a mass of light WIMP dark matter agrees with the recent observations of CoGeNT, DAMA, and CDMS. The obtained masses of φ- and dark matter particle are concordant with the coupling constant of after-GUT interaction αX 1/70 at MX 6 × 1010 GeV, and the decay rate φ ≈ 2 × 10-18\, s-1$. The cross-sections of the reactions in which dark matter particles can be produced are calculated