The Higgs boson has been in the news lately. Its detection (or at least the detection of a particle very similar to a singular Higgs) has been claimed by CERN. But as reported in various scientific publications, further analysis of the data from particle physicists at Argonne National Laboratory in Illinois suggests that CERN is just about as likely to have found evidence for more exotic varieties of the Higgs particle, called Higgs doublets or Higgs triplets. These “impostor” Higgs particles are part of a non-Standard Model interpretation of the Higgs concept, where several different Higgs-type particles (instead of just one) are together responsible for the Higgs field. In fact, a popular theory known as supersymmetry predicts at least five Higgs particles, and others predict many more.

What does Extended Heim Theory say of the Higgs? Here are snippets from various articles authored by Hauser and Droescher.

The 6 generators of O(2, q) for subspace S2 give rise to 6 Higgs fields (bosons) through which fermions are coming into existence (mass and charge). Six Higgs fields should exist, whose lightest particle mass should have, according to considerations from EHT, a mass of 182.7 ± 0.7 GeV.

The 6 anti-Higgs bosons of O(2,q) from subspace I2 procure mass and charge, including imaginary mass for the particles representing non-ordinary matter. In total there should exist twelve Higgs fields (two O(2,q) groups) that endow physical particles (fields) with their inherent charges.

It is assumed that the current of the superconducting electrons (Cooper pairs) causes a current of imaginary electrons. Imaginary particles are formed via the Higgs mechanism, for instance, as described by Kaku (Kaku, M.: Quantum Field Theory, Oxford, 1993).

Because of the twelve Higgs fields, 12 charges are proposed; four of them should be of gravitational nature. And that’s what is proposed in EHT, gravitophotons v0gp-, v0gp+, v0g, and v0q.