Gravity and electroweak sector from symmetry breaking of an SO(3,3) BF theory

Abstract

An SO(3,3) BF-type gauge theory is formulated on a six-dimensional spacetime of split signature (3,3), interpreted as the pre-electroweak-symmetry-breaking phase. A MacDowell--Mansouri-type symmetry breaking to SU(2)× SU(2) is implemented, and the corresponding stabilizer and coset structures are computed. The curvature decomposes into chiral sectors, and effective tetrads are introduced using components of the higher-dimensional connection. The resulting left and right sectors are formulated as constrained BF/Plebanski-like theories with appropriate simplicity and reality conditions. The six-dimensional theory yields two overlapping four-dimensional Lorentzian sectors of opposite signature, related via gluing constraints across their intersection. In the first sector, the selfdual two-forms ((+)) satisfy simplicity constraints that select the non-degenerate branch and reproduce Einstein gravity. Subsequently, the SU(2)R× U(1)Y dem U(1) dem breaking pattern is outlined which admits an ultra-soft regime consistent with current phenomenological bounds under sufficiently suppressed couplings. In the second sector, the antiself dual two-forms ((-)) satisfy analogous simplicity constraints, realizing weak gauge dynamics as gravity on the opposite-signature sector. Subsequently, the SU(2)L U(1)Y electroweak symmetry is realized within the Yang--Mills branch of the BF theory which incorporates the standard Higgs mechanism SU(2)L U(1)Y U(1)EM, recovering the conventional electroweak W, Z, and photon spectrum.