Treatise on the Topological Dynamics of Mass and Metric Stability via Quantized Spacetime Stiffness Abstract: This work establishes a deterministic framework for particle physics by modeling the spacetime manifold as a continuum with a finite modulus of rigidity (). We demonstrate that mass, spin, and charge are topological eigenvalues of stable metric solitons—specifically the Clifford Torus and the Hopf Fibration. By introducing a formal Stability Equation, we prove that these geometries are minimum energy states under metric tension. The Heisenberg Uncertainty Principle is derived as the elastic shear limit of the vacuum. An experimental protocol using high-intensity laser interferometry is proposed to measure the non-linear saturation of metric stiffness. Key highlights: Derivation of the Heisenberg Uncertainty Principle from metric elasticity. Resolution of mass-ratio constants through topological invariants. Proposal of the "Metric Phase Shift" experiment for vacuum stiffness validation. Framework for deterministic unified field theory.
André Belfort rolim (Thu,) studied this question.