Toward a Special E6 G(2) × SU(3)A Embedding for Standard Model and Dark Matter and an E7 Completion Proposal

Abstract

We developed a unified framework based on a special (non-regular) embedding of the exceptional group E6 in which the main stage of symmetry breaking chain realizes E6 G(2) × SU(3)A. The exceptional factor G(2) plays the role of a hidden strong sector, while SU(3)A acts as an ancestor of the electroweak gauge group. A minimal scalar sector is organized around a \(650\)-based \(E6\) Higgs sector. Its components (7,1) and (1,8) implement the subsequent breaking steps G(2) SU(3)C and SU(3)A SU(2)L× U(1)A. The speciality of this symmetry breaking establishes the feature of darkness. Defining an hypercharge from the t8 generator of SU(3)A is not sufficient to recover the exact Standard Model hypercharges, leading to the necessity of an E7 uplift which introduces a proper additional U(1)X factor. The special embedding naturally suppresses tree-level leptoquark couplings that typically mediate proton decay in regular GUTs. The scalar potential for the Higgs sectors has been constructed, deriving the heavy gauge-bosons spectrum and presenting a consistent one-loop running of the gauge couplings across the intermediate scales, which is shown to satisfy an E6 unification. The exotic states are organized in \(E7\)-derived vectorlike pairs and are made ultraheavy. The G(2) gluons ensemble confines into heavy dark glueballs with parametrically suppressed communication with SU(3)A and U(1)X sectors. Cosmological history is analyzed, including topological defects, inflation and reheating, demonstrating that monopole relics are naturally diluted. The resulting framework provides a minimal and internally consistent exceptional apparatus which includes the Standard Model and a dark matter sector which is secluded by the group-theoretic orthogonality.