Testing Dirac leptogenesis with the cosmic microwave background and proton decay
Julian Heeck, Jan Heisig, Anil Thapa
Abstract
The nature of neutrino masses and the matter-antimatter asymmetry of our universe are two of the most important open problems in particle physics today and are notoriously difficult to test with current technology. Dirac neutrinos offer a solution through a leptogenesis mechanism that hinges on the smallness of neutrino masses and resultant nonthermalization of the right-handed neutrino partners in the early universe. We thoroughly explore possible realizations of this Dirac leptogenesis idea, revealing new windows for highly efficient asymmetry generation. In many of them, the number of relativistic degrees of freedom, ${N}_{\mathrm{eff}}$, is severely enhanced compared to standard cosmology and offers a novel handle to constrain Dirac leptogenesis with upcoming measurements of the cosmic microwave background. Realizations involving leptoquarks even allow for low-scale postsphaleron baryogenesis and predict proton decay. These novel aspects render Dirac leptogenesis surprisingly testable.