Abstract
We investigate multi-lepton LHC signals arising from an extension at the grand unification scale of the standard minimal supersymmetric model (MSSM) involving right-handed neutrino superfields. In this framework neutrinos have Dirac masses and the mixed sneutrinos are the lightest supersymmetric particles and hence the dark matter candidates. We analyze the model parameter space in which the sneutrino is a good dark matter particle and has a direct detection cross-section compatible with the LUX bound. Studying the supersymmetric mass spectrum of this region, we find several signatures relevant for LHC, which are distinct from the predictions of the MSSM with neutralino dark matter. For instance two opposite sign and different flavor leptons, three uncorrelated leptons and long-lived staus are the most representative. Simulating both the signal and expected background, we find that the multi-lepton signatures and the long-lived stau are in the reach of the future run of LHC with a luminosity of 100/fb. We point out that if one of these signatures is detected, it might be an indication of sneutrino dark matter.
Highlights
JHEP04(2014)100 which scale as the logarithm of the supersymmetric masses, in particular with the stop masses
The particle physics model we analyze here is a far less investigated extension of the minimal supersymmetric standard model (MSSM) focused on the sneutrino, the scalar super-partner of the left-handed neutrino, which plays the role of dark matter candidate instead of the usual neutralino
In this paper we review the status of the sneutrino as dark matter after the Higgs boson mass measurements, by exploring the SUSY parameter space with the soft breaking terms fixed at the grand unification (GUT) scale, allowing for
Summary
JHEP04(2014)100 which scale as the logarithm of the supersymmetric masses, in particular with the stop masses. The latter must be rather high, well above 1 TeV unless the stop sector has maximal mixing, suggesting that the mass scale of SUSY particles could be substantially higher than expected from fine-tuning arguments This would make very challenging, if not impossible, to detect SUSY at LHC in a direct or indirect way [10–. Being the theory supersymmetric the superfield contains as well a scalar right-handed field, the scalar neutrino right Ñ This field, if at TeV scale, can mix with the left-handed partner νL and make the sneutrino, mostly right-handed, a viable dark matter candidate [24, 33,34,35]. In this paper we review the status of the sneutrino as dark matter after the Higgs boson mass measurements, by exploring the SUSY parameter space with the soft breaking terms fixed at the grand unification (GUT) scale, allowing for Supersymmetric framework
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