Abstract
We present a simple mechanism which allows the simultaneous generation of the baryon asymmetry of the Universe along with its dark matter content. To this goal, we employ the out-of-equilibrium decays of heavy bath states into a feebly coupled dark matter particle and Standard Model charged fermions. These decays lead to dark matter production via the freeze-in mechanism and, assuming that they further violate $CP$, can generate a viable matter-antimatter asymmetry in the resonant regime. We illustrate this mechanism by studying a particular realization of this general scenario, where the role of the heavy bath particles is played by $SU(3)_{\text{c}}\times SU(2)_{\text{L}}$-singlet vectorlike fermions with a non-zero hypercharge and dark matter is identified with a gauge-singlet real scalar field. We show that in the context of this simple model the cosmological constraints for the dark matter abundance and the baryon asymmetry are satisfied for masses of heavy vectorlike fermion states of a few TeV, potentially within reach of the High-Luminosity Run of the Large Hadron Collider. Dark matter, in turn, is predicted to be rather light, with a mass of a few keV.
Highlights
Among the numerous open questions in contemporary high-energy physics, the origin of cosmic dark matter (DM) and that of the baryon asymmetry in the Universe occupy a pivotal place
We discussed a mechanism for the simultaneous generation of the dark matter density and the baryon asymmetry of the Universe
We relied on the out-of-equilibrium decays of heavy bath particles into a dark matter state along with Standard Model charged fermions, which leads to dark matter production via the freeze-in mechanism
Summary
Among the numerous open questions in contemporary high-energy physics, the origin of cosmic dark matter (DM) and that of the baryon asymmetry in the Universe occupy a pivotal place. The fermions, which were taken to be singlets under the SM gauge group can, play the role of viable dark matter candidates through the freeze-in mechanism [25,26], whereas their CP-violating oscillations, in the presence of electroweak sphaleron transitions, can generate the observed baryon asymmetry of the Universe. GOUDELIS, PAPACHRISTOU, and SPANOS detail in the following, we consider a heavy particle species which is charged under (parts of) the SM gauge group and which can decay through feeble interactions into SM fermions along with a neutral particle The latter is our dark matter candidate, produced upon the decays of the heavy particle through the freeze-in mechanism, along the lines presented in Ref.
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