The Un-Probable Nature of Quantum Physics: Mechanical Foundations for Phenomena Attributed to Fundamental Randomness

Quantum mechanics describes statistical patterns without providing mechanical causation, then elevates this descriptive gap into a foundational principle: that nature is fundamentally probabilistic. This paper argues that probability in quantum theory reflects ignorance of underlying mechanics, not ontological randomness. Using the Free Range Electron (FRE) field framework established in prior work, we provide mechanical explanations for the photoelectric effect, reframe the energy equation as E= M×A(Mass times Action) rather than E= mc2, and identify neutrinos as free range electrons exceeding the local propagation velocity of light. The speed of light is shown to be a derived quantity dependent on stellar core mechanics, not a universal constant. These results eliminate the need for probability as a fundamental feature of physics and restore deterministic causation to phenomena currently attributed to quantum indeterminacy.