A lower bound on the right-handed neutrino mass from wash-in leptogenesis

Abstract

Leptogenesis is an attractive scenario for the generation of the baryon asymmetry of the Universe that relies on the dynamics of right-handed neutrinos (RHNs) in the seesaw extension of the Standard Model. In standard thermal leptogenesis, the RHN mass scale MN is subject to the Davidson--Ibarra bound, MN 109\,GeV, which builds on the assumption that RHN decays are responsible for the violation of both charge-parity invariance (CP) and baryon-minus-lepton number (B\!-\!L). In this paper, we relax this assumption in the context of the more flexible framework of wash-in leptogenesis, in which CP violation is encoded in the initial conditions and the only remaining task of the RHN decays is to violate B\!-\!L. Solving the relevant set of Boltzmann equations for vanishing initial baryon and lepton numbers (i.e., B = Le = Lμ = Lτ = 0 initially), we find that, in wash-in leptogenesis, the RHN mass scale can be as low as 7~TeV. Wash-in leptogenesis at such low RHN masses requires the presence of a primordial charge asymmetry between right-handed electrons and left-handed positrons. We discuss several possibilities for the origin of such an asymmetry and comment on its implications for the chiral instability of the Standard Model plasma.