Electroweak and supersymmetry breaking from the Higgs discovery

Abstract

We will explore the consequences on the electroweak breaking condition, the mass of supersymmetric partners and the scale at which supersymmetry is broken, for arbitrary values of the supersymmetric parameters tan(beta) and the stop mixing Xt, which follow from the Higgs discovery with a mass mH 126 GeV at the LHC. Within the present uncertainty on the top quark mass we deduce that radiative breaking requires tan(beta) 7 for maximal mixing Xt 6, and tan(beta) 20 for small mixing Xt 1. The scale at which supersymmetry is broken M can be of order the unification or Planck scale only for large values of tan(beta) and negligible mixing Xt 0. On the other hand for maximal mixing and large values of tan(beta) supersymmetry should break at scales as low as M 105 GeV. The uncertainty in those predictions stemming from the uncertainty in the top quark mass, i.e. the top Yukawa coupling, is small (large) for large (small) values of tan(beta). In fact for tan(beta)=1 the uncertainty on the value of M is of several orders of magnitude.