Impact of flavor changing processes on prospects for majoron discovery at intensity-frontier searches

Abstract

The singlet majoron J is the pseudo-Nambu-Goldstone boson of a global, anomaly-free U(1)B-L symmetry whose spontaneous breaking generates Majorana masses for right-handed neutrinos. At tree level, the only direct coupling of J to Standard Model fields is J m/f (where m denotes the light neutrino mass and f the B-L breaking scale). Couplings to charged fermions and gauge bosons, in contrast, arise only at loop level. Consequently, J can be long-lived over wide regions of parameter space, motivating displaced-decay searches. We study majoron production and displaced decays at proton beam dump experiments, neutrino facilities, and LHC forward detectors (including DUNE, NA62, FASER/FASER2, MATHUSLA, and SHiP), and we quantify the resulting reach in the (mJ,\,f) plane. We show that, for realistic seesaw-induced coupling textures, lepton-flavor-violating (LFV) τ decays τ J (=e,μ) dominate majoron production at these facilities and can extend sensitivity into the intermediate-mass window mJ 0.2-1.7~GeV, complementary to supernova bounds at lower masses and to dedicated LFV searches at higher masses. We also identify physically consistent benchmark textures for the matrix K=MD MD/(vf) with MD denoting the Dirac mass matrix and v the electroweak scale (including positive semidefinite ``anarchical'', single-flavor, and CP-violating cases) and map their impact on experimental reach.