The Theory of Primordiarity: ExtendedMathematical Framework

This expanded edition formalizes and extends the Theory of Primordiarity, a novel ontological framework proposing that reality emerges from the continuous interaction between existence (E) and potential (P). The theory asserts that reality does not move toward a final equilibrium but persists through a recursive process of emergence. Rather than a deterministic system solving toward resolution, Primordiarity describes an ever-evolving state where structure (1) and possibility (0) remain in constant negotiation.

This framework provides a fresh perspective on several fundamental physics concepts. It suggests that quantum uncertainty arises from unresolved potential states, reinforcing the idea that wave function collapse is not an instantaneous event but an emergent process. In relativity, the model proposes that singularities, such as black holes, do not represent absolute endpoints but instead transition phases leading to white hole expansion. This aligns with recent theoretical work suggesting black holes may undergo transformation rather than complete collapse. Additionally, the entropy-driven model supports the notion that time is not a fundamental dimension but an emergent property dictated by structural evolution.

By integrating these equations with established physics principles, this paper presents a mathematically grounded model for understanding the persistence of reality. The results suggest that reality is neither purely deterministic nor entirely stochastic but is governed by a structured, evolving interplay between what is and what could be. Implications extend across quantum mechanics, general relativity, thermodynamics, and cosmology, providing a foundation for further exploration into the intersection of physics, information theory, and emergence.