This article presents a unified theoretical framework where the geometry of spacetime, the inertia of matter, and quantum non-locality emerge from a single fundamental substrate: a vibrational network. We model space as a dynamic network of vibrating nodes, its elastic properties calibrated by the fundamental constants \ (\) and \ (c \). Mass is not a primitive property but is identified with the energy stored in the deformation of this network. The non-linearity of this medium at high energy allows for the self-trapping of waves into stable structures identified as particles. A reflection-based IN/OUT wave mechanism confers upon these particles an inherently non-local character, providing a mechanical explanation for the violation of Bell's inequalities and the holographic principle. A key result is the formal derivation of the Planck scale \ (P \) and the quantum of action \ (\) from the network's properties. Crucially, we demonstrate how General Relativity emerges from the dynamics of this network as a refractive effect, where energy density variations determine the effective "refractive index" of space, naturally leading to geodesic deviation and curvature. In this model, inertial mass \ (mᵢ \) and gravitational mass \ (mg \) are distinct emergent properties of a shared underlying deformation, linked by the gravitational constant \ (G \), which quantifies the network's susceptibility to deformation.
G. Furne Gouveia (Tue,) studied this question.