Hybrid seesaw leptogenesis and TeV singlets

TL;DR

This paper introduces a hybrid seesaw model that combines high-scale and TeV-scale physics to explain neutrino masses and leptogenesis, predicting new testable particles and addressing limitations of previous models.

Contribution

The work proposes a novel hybrid seesaw mechanism embedding high-scale and TeV-scale physics, enabling successful leptogenesis with natural couplings and richer phenomenology.

Findings

Predicts new TeV-scale particles accessible at colliders

Enlarges the allowed high-scale singlet mass range for leptogenesis

Includes potential astrophysical and cosmological signatures

Abstract

The appealing feature of inverse seesaw models is that the Standard Model (SM) neutrino mass emerges from the exchange of TeV scale singlets with sizable Yukawa couplings, which can be tested at colliders. However, the tiny Majorana mass splitting between TeV singlets, introduced to accommodate small neutrino masses, is left unexplained. Moreover, we argue that these models suffer from a structural limitation that prevents a successful leptogenesis if one insists on having unsuppressed Yukawa couplings and TeV scale singlets. In this work we propose a hybrid seesaw model, where we replace the mass splitting with a coupling to a high scale seesaw module including a TeV scalar. We show that this structure achieves the goal of filling both the above gaps with couplings of order unity. The necessary structure automatically arises embedding the seesaw mechanism in composite Higgs models, but may also be enforced by new gauge symmetries in a weakly-coupled theory. Our hybrid seesaw models have distinguishing features compared to the standard high scale type-I seesaw and inverse seesaw. Firstly, they have much richer phenomenology. Indeed, they generally predict new TeV scale physics (including scalars) potentially accessible at present and future colliders, whereas weakly-coupled versions may also have astrophysical and cosmological signatures due to the presence of a light Nambu-Goldstone boson coupled to neutrinos. Secondly, our scenario features an interesting interplay between high scale and TeV scale physics in leptogenesis and enlarges the range of allowed high scale singlet masses beyond the usual $\sim 10^9-10^{ 15 }$ GeV, without large hierarchies in the Yukawa couplings nor small mass splitting among the singlets.