We present the Homogeneous Compression Theory (HCT), a framework in which particles, interactions, and gravitational phenomena emerge from the dynamics of a fundamental compression field of space. In this approach, matter is interpreted as localized solitonic configurations of a complex compression field whose amplitude represents organized spatial compression and whose phase encodes internal orientation dynamics. Electric charge arises from phase rotation of the compression field, while electromagnetic interactions correspond to propagating flux modes. Gravitational effects emerge from large-scale gradients of the compression background produced by localized energy concentrations. The theory naturally reproduces Coulomb interactions, the Newtonian gravitational potential in the weak-field limit, and the structure of atomic bound states. The fine-structure constant is interpreted as a measure of the coupling between internal soliton dynamics and propagating compression modes. The framework provides a unified conceptual picture linking particle properties, field interactions, and spacetime structure within a single compression-based field theory.
Garcia Pablo (Sat,) studied this question.