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Gravitational footprints of massive neutrinos and lepton number breaking

Andrea Addazi, Antonino Marcianò, A. Morais, Roman Pasechnik, Rahul Srivastava, J. W. F. Valle

2020Physics Letters B30 citationsDOIOpen Access PDF

Abstract

We investigate the production of primordial Gravitational Waves (GWs) arising from First Order Phase Transitions (FOPTs) associated to neutrino mass generation in the context of type-I and inverse seesaw schemes. We examine both “high-scale” as well as “low-scale” variants, with either explicit or spontaneously broken lepton number symmetry U(1)L in the neutrino sector. In the latter case, a pseudo-Goldstone majoron-like boson may provide a candidate for cosmological dark matter. We find that schemes with softly-broken U(1)L and with single Higgs-doublet scalar sector lead to either no FOPTs or too weak FOPTs, precluding the detectability of GWs in present or near future measurements. Nevertheless, we found that, in the majoron-like seesaw scheme with spontaneously broken U(1)L at finite temperatures, one can have strong FOPTs and non-trivial primordial GW spectra which can fall well within the frequency and amplitude sensitivity of upcoming experiments, including LISA, BBO and u-DECIGO. However, GWs observability clashes with invisible Higgs decay constraints from the LHC. A simple and consistent fix is to assume the majoron-like mass to lie above the Higgs-decay kinematical threshold. We also found that the majoron-like variant of the low-scale seesaw mechanism implies a different GW spectrum than the one expected in the high-scale seesaw. This feature will be testable in future experiments. Our analysis shows that GWs can provide a new and complementary portal to test the neutrino mass generation mechanism.

Topics & Concepts

PhysicsParticle physicsSeesaw molecular geometryNeutrinoHiggs bosonSeesaw mechanismLepton numberPhysics beyond the Standard ModelLeptonDark matterNuclear physicsElectronParticle physics theoretical and experimental studiesDark Matter and Cosmic PhenomenaNeutrino Physics Research
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