Abstract
We explore the possibility that physics at the TeV scale possesses approximate $N = 2$ supersymmetry, which is reduced to the $N=1$ minimal supersymmetric extension of the Standard Model (MSSM) at the electroweak scale. This doubling of supersymmetry modifies the Higgs sector of the theory, with consequences for the masses, mixings and couplings of the MSSM Higgs bosons, whose phenomenological consequences we explore in this paper. The mass of the lightest neutral Higgs boson $h$ is independent of $\tan \beta$ at the tree level, and the decoupling limit is realized whatever the values of the heavy Higgs boson masses. Radiative corrections to the top quark and stop squarks dominate over those due to particles in $N=2$ gauge multiplets. We assume that these radiative corrections fix $m_h \simeq 125$ GeV, whatever the masses of the other neutral Higgs bosons $H, A$, a scenario that we term the $h$2MSSM. Since the $H, A$ bosons decouple from the $W$ and $Z$ bosons in the $h$2MSSM at tree level, only the LHC constraints on $H, A$ and $H^\pm$ couplings to fermions are applicable. These and the indirect constraints from LHC measurements of $h$ couplings are consistent with $m_A \gtrsim 200$ GeV for $\tan \beta \in (2, 8)$ in the $h$2MSSM.
Highlights
Experimental constraints coming from measurements of the h(125) Higgs boson [37] and searches for the heavier minimal supersymmetric extension of the Standard Model (MSSM) Higgs bosons
We explore the possibility that physics at the TeV scale possesses approximate N = 2 supersymmetry, which is reduced to the N = 1 minimal supersymmetric extension of the Standard Model (MSSM) at the electroweak scale
This doubling of supersymmetry modifies the Higgs sector of the theory, with consequences for the masses, mixings and couplings of the MSSM Higgs bosons, whose phenomenological consequences we explore in this paper
Summary
The left panel of figure 1 shows the tree-level N = 1 MSSM CP-even neutral Higgs boson masses as functions of mA for different values of tan β, and we see that mh increases with tan β, its upper limit being mZ. The right panel of figure 1 shows the corresponding N = 2 CP-even neutral Higgs boson masses at the tree level, where we see that mh = mZ independently of mA and tan β, and that mH crosses mh without the ‘level repulsion’ effect seen in the left panel. Which satisfies the relation −π/2 ≤ α ≤ 0 This implies that at the tree level the N = 2 theory realizes automatically the decoupling limit, in which the lighter CP-even neutral Higgs boson h has Standard Model-like couplings and the heavier one, H, does not couple to gauge bosons
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