k-Foam Theory: Elastic Foam Model of Space and Unified Description of Physical Phenomena

In 1915, Albert Einstein rewrote gravity not as a force, but as the geometric distortion of space. For the next 30 years, he pursued the dream of describing all physical phenomena—including electromagnetism and quantum mechanics—through pure geometry. He was right, but one piece was missing: the physical substance of what was distorting.

This paper presents k-Foam Theory, a hypothetical framework that provides this missing piece. Beginning from a simple survival simulation, the theory proposes that space is not a continuous void, but a discrete elastic foam grid comprised of regular octahedra (k=6).

By replacing the 'magic' of unexplainable forces with the mechanical topology of k-values (3, 4, and 6), this theory attempts to complete the landscape Einstein envisioned. Five independent physical constants—proton radius, nuclear force range, Weinberg angle, electroweak scale, and Higgs mass—are derived from a single geometric framework with errors within 2%. Additional derivations include the proton mass (0.073% error), lepton generation mass ratios, the dark matter/baryon ratio, and the geometric slip rate of the fine structure constant (α⁻¹ ≈ 137). Furthermore, Maxwell's equations and quantum entanglement are geometrically redefined, demonstrating that photons are not digital coins, but analog vectors.

This theory does not negate existing physics but attempts a fundamental reinterpretation of its premises. God does not play dice; there was never a dice to begin with. There is only geometry.