Unification of Couplings and the Top Quark Sector in the Minimal Supersymmetric Standard Model
Abstract
I analyze the predictions for the strong gauge coupling, α3(MZ) , and the top quark and light Higgs masses in the framework of gauge and bottom-tau Yukawa coupling unification in the minimal supersymmetric standard model. These predictions depend on the effective supersymmetric threshold scale TSUSY, which is only very slightly dependent on the squark and slepton masses, and strongly dependent on the Higgsino masses as well as on the mass ratio of the gauginos of the strong and weak interactions. Within the minimal supersymmetry breaking scheme and for supersymmetric masses below or of the order of 1 TeV, I obtain α3(MZ) ≥ 0.116, while, if the running bottom quark mass at the physical mass is constrained to be mb(Mb) ≤ 4.1 GeV, then, for moderate values of β, perturbative unification is achieved only if α3(MZ) ≤ 0.124. Unification of gauge and bottom-tau Yukawa couplings yield predictions for the top quark mass, 140 GeV ≤ Mt ≤ 210 GeV for 1 ≤ β ≤ 30, which are remarkably close to the infrared quasi fixed point values for this quantity. For the light Higgs mass I obtain mh ≤ 130(165) GeV if the characteristic squark mass is below 1 (10) TeV.
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