Light top squarks in U(1)R-lepton number model with a right handed neutrino and the LHC

Abstract

We investigate the phenomenology of top squarks at the Large Hadron Collider (LHC) in a supersymmetric model where lepton number is identified with an approximate U(1)R symmetry in such a way that one of the left chiral sneutrinos can acquire a large vacuum expectation value (vev) and can play the role of the down-type Higgs. This R-symmetry allows a subset of trilinear R-parity violating interactions, which determine the collider phenomenology of this model in a significant way. The gauginos are Dirac particles and gluinos are relatively heavy in this class of models. The model contains a right handed neutrino superfield, which gives a tree level mass to one of the active neutrinos. An order one neutrino Yukawa coupling also helps enhance the Higgs boson mass at the tree level and results in a very light bino-like neutralino ( 20) with mass around a few hundred MeV, which is a carrier of missing (transverse) energy (). The model can accommodate two rather light top squarks, compatible with the observed mass of the Higgs boson. The lighter top squark ( t1) can decay into t20, and thus the signal would be similar to the signal of top quark pair production at the LHC. In addition, fully visible decays such as t2 → b e+ can give rise to interesting final states. Such signals at the LHC combined with other features like a heavy gluino could provide a strong evidence for this kind of a model. Our analysis shows that m t1 575~(750) GeV and m t2 1.2~(1.4) TeV can be probed with 5σ statistical significance at the 13 TeV LHC with 300~(3000) fb-1 of integrated luminosity. Finally, we observe that in the presence of super-light carriers of , the so-called `stealth' top squark scenario may naturally appear in our model.