Abstract
Current analyses of the LHC data put stringent bounds on strongly interacting supersymmetric particles, restricting the masses of squarks and gluinos to be above the TeV scale. However, the supersymmetric electroweak sector is poorly constrained. In this article we explore the consistency of possible LHC missing energy signals with the broader phenomenological structure of the electroweak sector in low energy supersymmetry models. As an example, we focus on the newly developed Recursive Jigsaw Reconstruction analysis by ATLAS, which reports interesting event excesses in channels containing di-lepton and tri-lepton final states plus missing energy. We show that it is not difficult to obtain compatibility of these LHC data with the observed dark matter relic density, the bounds from dark matter direct detection experiments, and the measured anomalous magnetic moment of the muon. We provide analytical expressions which can be used to understand the range of gaugino masses, the value of the Higgsino mass parameter, the heavy Higgs spectrum, the ratio of the Higgs vacuum expectation values $\tan \beta$, and the slepton spectrum obtained in our numerical analysis of these observables.
Highlights
The minimal supersymmetric standard model (MSSM) [1,2,3] provides a well-defined extension of the standard model (SM)
In this article we have presented a study of the current constraints on the electroweak sector in low energy supersymmetry models
We have taken gaugino and Higgsino mass parameters that can be consistent with a new physics interpretation of recent event excesses in the ATLAS search for electroweakinos using the recursive jigsaw reconstruction (RJR) method
Summary
The minimal supersymmetric standard model (MSSM) [1,2,3] provides a well-defined extension of the standard model (SM). By assuming the event excesses reported by the ATLAS collaboration to be a signal of new physics, we determine the necessary MSSM gaugino sector leading to an explanation of the observed signatures. We combine this information with that provided by the observed dark matter (DM) relic density, the current bounds from DM direct and indirect detection experiments, and the measured value of the anomalous magnetic moment of the muon aμ.
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