ZBL portal dark matter and LHC Run-2 results

Abstract

We consider a concise dark matter scenario in the minimal gauged B-L extension of the Standard Model (SM), where the global B-L (baryon number minus lepton number) symmetry in the SM is gauged, and three generations of right-handed neutrinos and a B-L Higgs field are introduced. Associated with the B-L gauge symmetry breaking by a VEV of the B-L Higgs field, the seesaw mechanism for generating the neutrino mass is automatically implemented after the electroweak symmetry breaking in the SM. In this model context, we introduce a Z2-parity and assign an odd parity for one right-handed neutrino while even parities for the other fields. Therefore, the dark matter candidate is identified as the right-handed Majorana neutrino with odd Z2 parity, keeping the minimality of the particle content intact. When the dark matter particle communicates with the SM particles mainly through the B-L gauge boson (ZBL boson), its relic abundance is determined by only three free parameters, the B-L gauge coupling (αBL), the ZBL boson mass (mZ) and the dark matter mass (mDM). With the cosmological upper bound on the dark matter relic abundance we find a lower bound on αBL as a function of mZ. On the other hand, we interpret the recent LHC Run-2 results on search for Z boson resonance to an upper bound on αBL as a function of mZ. Combining the two results we identify an allowed parameter region for this "ZBL portal" dark matter scenario, which turns out to be a narrow window with the lower mass bound of mZ > 2.5 TeV.