Distinguishing between MSSM and NMSSM through F=2 processes

Abstract

We study deviations between MSSM and Z3-invariant NMSSM, with respect to their predictions in F=2 processes. We find that potentially significant effects arise either from the well known double-penguin diagrams, due to the extra scalar NMSSM states, or from neutralino-gluino box contributions, due to the extended neutralino sector. Both are discussed to be effective in the large β regime. Enhanced genuine-NMSSM contributions in double penguins are expected for a light singlet spectrum (CP-even,CP-odd), while the magnitude of box effects is primarily controlled through singlino mixing. The latter is found to be typically subleading (but non-negligible) for λ 0.5, however it can become dominant for λ O(1). We also study the low β regime, where a distinction between MSSM and NMSSM can come instead due to experimental constraints, acting differently on the allowed parameter space of each model. To this end, we incorporate the LHC Run-I limits from H→ Z Z, A → hZ and H → τ non-observation along with Higgs observables and set (different) upper bounds for new physics contributions in F=2 processes. We find that a 25\% contribution in Ms(d) is still possible for MFV models, however such a large effect is nowadays severely constrained for the case of MSSM, due to stronger bounds on the charged Higgs masses.