The SM expected branching ratio for h γ γ and an excess for h Z γ

Abstract

The recent measurements of h Z γ from ATLAS and CMS show an excess of the signal strength μZ = (σ· B)obs/(σ· B)SM=2.2 0.7, normalized as 1 in the standard model~(SM). If confirmed, it would be a signal of new physics (NP) beyond the SM. We study NP explanation for this excess. In general, for a given model, it also affects the process h γ γ. Since the measured branching ratio for this process agrees well with the SM prediction, the model is severely constrained. We find that a minimally fermion singlets and doublet extended NP model can explain simultaneously the current data for h Z γ and h γγ. There are two solutions. Although both solutions enhance the amplitude of h Z γ to the observed one, in one of the solutions the amplitude of h γ γ flips sign to give the observ ed branching ratio. This seems to be a contrived solution although cannot be ruled out simply using branching ratio measurements alone. However, we find another solution that naturally enhances h Z γ to the measured value, but keeps the amplitude of h γγ close to its SM prediction. We also comment on the phenomenology associated with these new fermions.