The Deterministic Mechanism of the Double-Slit Experiment: A Baryonic Matter Physics Explanation

This paper presents the first deterministic reinterpretation of the double-slit experiment based entirely on the Konkle–Baryonic Unified Framework (KB-Framework). Instead of invoking wavefunction collapse, probability distributions, or observer-dependent indeterminacy, the analysis derives the interference pattern from a real physical mechanism: curvature–compression fields generated by the Baryonic Matter (BM) structure surrounding the slits.In this model, every photon possesses a well-defined geometric extent (a curvature envelope), determined by the Konkle–Baryonic Unified Equation hf=mc2hf = m c^{2}hf=mc2. When a photon approaches the double-slit assembly, this envelope interacts deterministically with the two-slit geometry. The BM-field surrounding the slits produces <b>t</b>wo overlapping curvature channels—not probability waves, but structural field distortions. The photon does not “take both paths”; it takes one trajectory, but its extended curvature interacts with both slits, and the resulting compression pattern determines the final landing point.The paper demonstrates:A deterministic mechanism that entirely replaces wavefunction collapse.How Snap-Point field threshold<b>s</b> reproduce discrete bands in the interference pattern.Why the interference persists even when photons are fired one at a time.Why placing detectors at the slits destroys the interference pattern (detector BM-fields collapse the curvature envelope before dual-channel interaction).How the mechanism extends naturally to electrons, neutrons, and even large molecules without probability-based assumptions.This publication establishes the priority claim that the double-slit phenomenon arises from BM-field geometry and curvature–compression interactions — not quantum randomness.