Matter and dark matter asymmetry from a composite Higgs model

TL;DR

This paper introduces a composite Higgs model with heavy neutrinos that explains matter-antimatter asymmetry and dark matter simultaneously through low-scale leptogenesis and bound state decays.

Contribution

It presents a novel low-scale leptogenesis mechanism within composite Higgs models, linking dark matter stability and asymmetry generation via heavy neutrino decays.

Findings

Asymmetry generated at TeV scale via resonant bound states.

Viable dark matter mass range identified based on coupling strength.

Model predicts observable low-energy processes related to dark matter.

Abstract

We propose a low scale leptogenesis scenario in the framework of composite Higgs models supplemented with singlet heavy neutrinos. One of the neutrinos can also be considered as a dark matter candidate whose stability is guaranteed by a discrete $\mathbb{Z}_2 $ symmetry of the model. In the spectrum of the strongly coupled system, bound states heavier than the pseudo Nambu-Goldstone Higgs boson can exist. Due to the decay of these states to heavy right-handed neutrinos, an asymmetry in the visible and dark sector is simultaneously generated. The resulting asymmetry is transferred to the standard model leptons which interact with visible right-handed neutrinos. We show that the sphaleron-induced baryon asymmetry can be provided at the TeV scale for resonant bound states. Depending on the coupling strength of dark neutrino interaction, a viable range of the dark matter mass is allowed in the model. Furthermore, taking into account the effective interactions of dark matter, we discuss low-energy processes and experiments.