Primordial black holes and magnetic fields in conformal neutrino mass models

Abstract

Sufficiently strong and long-lasting first-order phase transitions can produce primordial black holes (PBHs) that contribute substantially to the dark matter abundance of the Universe, and can produce large-scale primordial magnetic fields. We study these mechanisms in a generic class of conformal U(1) models that also explain active neutrino oscillation data via the type-I seesaw mechanism. We find that phase transitions that occur at seesaw scales between 104 GeV and 1011 GeV produce gravitational wave signals (from the dynamics of the phase transition and from the decay of cosmic string loops) at LISA/ET that can be correlated with microlensing signals of PBHs at the Roman Space Telescope, while scales near 1011 GeV can be correlated with Hawking evaporation signals at future gamma-ray telescopes. LISA can probe the entire range of PBH masses between 1× 10-16M and 8× 10-11M if PBHs fully account for the dark matter abundance. For Z' masses between 5 TeV and 100 TeV, and 3 TeV right-handed neutrinos, helical magnetic fields can be produced with magnitudes 10-16-10-13 G and coherence lengths 10-4-10-2 Mpc, above current blazar lower bounds.