Testing neutrino mass hierarchy under type-II seesaw scenario in U (1) X at colliders

The origin of tiny neutrino mass is a long standing unsolved puzzle of the Standard Model (SM) which allows us to consider scenarios beyond the Standard Model (BSM) in a variety of ways. One of them being the gauge extension of the SM could be realized as in the form of an anomaly free, general U (1) X extension of the SM where an SU (2) L triplet scalar being charged under U (1) X gauge group is introduced through a Dirac Yukawa coupling with the SM lepton doublet. Once the triplet scalar generates VEV, light neutrinos could acquire tiny Majorana mass and hence affecting the decay modes of the triplet scalar involving the neutrino oscillation data for different neutrino mass hierarchies. After the breaking of U (1) X scenarios, a neutral BSM, neutral gauge boson (Z^) acquires mass which interact differently with the left and right handed fermions. Satisfying the recent LHC bounds on the triplet scalar and Z^ production, we study the pair production of the triplet scalar at LHC, e^-e^+ and ^-^+ colliders followed by its decay into dominant mode depending on the neutrino mass hierarchy. Generating the SM generic backgrounds, we study the possible signal significance of four lepton final states. We also compare our results with the purely SM gauge mediated triplet scalar pair production followed by four lepton final states which could be significant only in ^- ^+ collider.