Thermal Resonant Leptogenesis produces the observed baryon asymmetry via a dominant thermal channel from Higgs decays and lepton-doublet coherences, without requiring quasi-degenerate sterile neutrinos.
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Tera-Z factories can produce millions of heavy neutral leptons and billions of axion-like particles under optimistic assumptions, turning them into exotics factories for discovery and detailed study.
Three right-handed neutrinos below the electroweak scale can explain both neutrino masses and baryon asymmetry, with GeV-scale masses testable in B meson decays at the LHC using argon collisions for improved sensitivity.
citing papers explorer
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Dominant Thermal Resonant Mechanism for Low-Scale Leptogenesis
Thermal Resonant Leptogenesis produces the observed baryon asymmetry via a dominant thermal channel from Higgs decays and lepton-doublet coherences, without requiring quasi-degenerate sterile neutrinos.
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New Particles at the Z-Pole: Tera-Z factories as discovery and precision machines
Tera-Z factories can produce millions of heavy neutral leptons and billions of axion-like particles under optimistic assumptions, turning them into exotics factories for discovery and detailed study.
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Testability of leptogenesis with three RH-neutrinos below the electroweak scale
Three right-handed neutrinos below the electroweak scale can explain both neutrino masses and baryon asymmetry, with GeV-scale masses testable in B meson decays at the LHC using argon collisions for improved sensitivity.