Minimal Majoron Dark Matter from a Discrete ZN Gauge Symmetry

Abstract

We investigate majoron dark matter in a minimal setup, where the Standard Model is extended by three right-handed neutrinos and a complex scalar field. The theory is defined by an exact discrete gauge symmetry, ZN⊂ U(1)B-L, while the global U(1)B-L symmetry emerges only as an accidental symmetry at low energies. For nontrivial choices of the discrete symmetry ZN, such as Z5, Z7, Z11, and Z13, Planck-suppressed operators explicitly break this accidental symmetry and generate a small majoron mass, making the resulting pseudo-Nambu--Goldstone boson a well-motivated dark matter candidate. We study its production via the misalignment mechanism after inflation, considering both radiation-dominated and early matter-dominated cosmological histories, and confront the viable parameter space with isocurvature bounds, cosmological constraints, and indirect dark matter searches. We find that the Z5 model is excluded by limits on the dominant dark matter decay into neutrinos, whereas the other models remain viable. In particular, the Z7 scenario predicts a majoron mass in the 1--10\, MeV range and can be sensitively probed by future MeV gamma-ray observations, especially with COSI, through the 511\,keV line from the majoron decay into an electron--positron pair and the monochromatic gamma-ray line from its decay into two photons.

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