This work introduces a finite-capacity vacuum framework (QUOT/VCI) providing a unified geometric closure of key electroweak precision observables. Starting from a single coherence operator, the construction reproduces: the W-boson mass from a universal vacuum relaxation time, the full Z-pole sextet MZ, ΓZ, sin²θₑff, σₕ⁰, R_ℓ, Rb via node curvature, the Higgs resonance as a transverse rigidity mode, fermion Yukawa hierarchies from discrete topological coherence paths, the muon as the first oscillatory eigenmode of a minimal coherence filter, and the fine-structure constant α as a vacuum transfer impedance. No additional normalization parameters are introduced. All quantities emerge from the same curvature-controlled architecture. The framework closes W, Z, Higgs, Yukawas, and α within a single coherent structure, achieving agreement with experimental values up to 10⁻⁶ precision for α. Rather than proposing new particles, this approach reinterprets existing Standard Model parameters as stationary eigenvalues of a finite-capacity vacuum network. Charged-lepton generations appear as coherence eigenmodes (electron: DC reference, muon: phase bridge, tau: rigidity limit), while color acts as chromatic friction. This manuscript provides a complementary structural solution to electroweak precision physics, offering a unified geometric interpretation of masses, couplings, and constants that previously required independent inputs.
jose fabian vallejos (Sat,) studied this question.
Synapse has enriched 5 closely related papers on similar clinical questions. Consider them for comparative context: