Octonion Internal Space Algebra for the Standard Model

Abstract

The paper surveys recent progress in the search for an appropriate internal space algebra for the Standard Model (SM) of particle physics. As a starting point serve Clifford algebras involving operators of left multiplication by octonions. A central role is played by a distinguished complex structure which implements the splitting of the octonions O = C C3 reflecting the lepton-quark symmetry. Such a complex structure in C10 is generated by the C6(⊂ C8⊂ C10) volume form, ω6 = γ1 ·s γ6, left invariant by the Pati-Salam subgroup of Spin(10), G PS = Spin (4) × Spin (6) / Z2. While the Spin(10) invariant volume form ω10=γ1 ... γ10 is known to split the Dirac spinors of C10 into left and right chiral (semi)spinors, P = 12 (1 - iω6) is interpreted as the projector on the 16-dimensional particle subspace (annihilating the antiparticles). The standard model gauge group appears as the subgroup of GPS that preserves the sterile neutrino (identified with the Fock vacuum). The Z2-graded internal space algebra A is then included in the projected tensor product: A⊂ PC10P=C4 P C60P. The Higgs field appears as the scalar term of a superconnection, an element of the odd part, C41, of the first factor. The fact that the projection of C10 only involves the even part C60 of the second factor guarantees that the colour symmetry remains unbroken. As an application we express the ratio mHmW of the Higgs to the W-boson masses in terms of the cosine of the theoretical Weinberg angle.