Probing 0ββ and μ eγ via Fully Determined Dirac Mass Terms in LRSM with Double Seesaw

Abstract

Neutrinoless double beta decay (0ββ) and charged lepton flavor violation (cLFV) experiments provide promising avenues to probe new physics contributions from extended neutrino sectors in beyond Standard Model (BSM) scenarios. We consider a Left-Right Symmetric Model (LRSM) extended with three generations of sterile neutrinos to realize a double type-I seesaw mechanism for light neutrino mass generation. The double seesaw induces maximal lepton number violation in the right-handed sector and facilitates enhanced Majorana masses for right-handed neutrinos, thereby leading to their dominant contributions in both cLFV and 0ββ processes. We perform a comprehensive exploration of the parameter space for new-physics contributions to the cLFV decay μ e γ and to 0ββ, considering two different textures for the Dirac mass matrices: (i) a symmetry-motivated limit with MD 1, and (ii) a texture fully determined by the model framework. A detailed analysis of the common parameter regions accessible to current experiments like KamLAND-Zen and LEGEND-200, and upcoming experiments, such as MEG-II and LEGEND-1000, is presented, underscoring the phenomenological relevance of this framework. Our results aim to provide optimistic benchmarks for future searches targeting right-handed current-mediated neutrino interactions.