Unified Maximally Natural Supersymmetry

Abstract

Maximally Natural Supersymmetry, an unusual weak-scale supersymmetric extension of the Standard Model based upon the inherently higher-dimensional mechanism of Scherk-Schwarz supersymmetry breaking (SSSB), possesses remarkably good fine tuning given present LHC limits. Here we construct a version with precision SU(2) L × U(1) Y unification: 2 θW(MZ) 0.231 is predicted to 2\% by unifying SU(2) L × U(1) Y into a 5D SU(3) EW theory at a Kaluza-Klein scale of 1/R5 4.4\, TeV, where SSSB is simultaneously realised. Full unification with SU(3) C is accommodated by extending the 5D theory to a N=4 supersymmetric SU(6) gauge theory on a 6D rectangular orbifold at 1/R6 40 \, TeV. TeV-scale states beyond the SM include exotic charged fermions implied by SU(3) EW with masses lighter than 1.2\, TeV, and squarks in the mass range 1.4\, TeV - 2.3\, TeV, providing distinct signatures and discovery opportunities for LHC run II.