Abstract
In the framework of the (B − L) Supersymmetric Standard Model (BLSSM), we assess the ability of ground and space based experiments to establish the nature of its prevalent Dark Matter (DM) candidate, the sneutrino, which could either be CP-even or -odd. Firstly, by benchmarking this theory construct against the results obtained by the Planck spacecraft, we extract the portions of the BLSSM parameter space compliant with relic density data. Secondly, we show that, based on current sensitivities of the Fermi Large Area Telescope (FermiLAT) and their future projections, the study of high-energy γ-ray spectra will eventually enable us to extract evidence of this DM candidate through its annihilations into W+W− pairs (in turn emitting photons), in the form of both an integrated flux and a differential energy spectrum which cannot be reconciled with the assumption of DM being fermionic (like, e.g., a neutralino), although it should not be possible to distinguish between the scalar and pseudoscalar hypotheses. Thirdly, we show that, while underground direct detection experiments will have little scope in testing sneutrino DM, the Large Hadron Collider (LHC) may be able to do so in a variety of multi-lepton signatures, with and without accompanying jets (plus missing transverse energy), following data collection during Run 2 and 3.
Highlights
ΝIm, 661 GeV Eγ [GeV]computed in (4.1) is itself a subject of dedicated analyses and experimental searches based on FermiLAT data
We show that, based on current sensitivities of the Fermi Large Area Telescope (FermiLAT) and their future projections, the study of highenergy γ-ray spectra will eventually enable us to extract evidence of this Dark Matter (DM) candidate through its annihilations into W +W − pairs, in the form of both an integrated flux and a differential energy spectrum which cannot be reconciled with the assumption of DM being fermionic, it should not be possible to distinguish between the scalar and pseudoscalar hypotheses
Once consistent solutions are identified, we investigate possible signatures of RH sneutrino DM in Fermi Large Area Telescope (FermiLAT) and Large Hadron Collider (LHC) data for some benchmark points in sections 4 and 5, respectively
Summary
Within a TeV scale BLSSM with Type-I seesaw and very small neutrino Yukawa coupling, Yν
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