Biological zinc adopts tetrahedral coordination — 4-coordinate, four ligands, confirmed by over 4,000 structures in the Protein Data Bank. The tetrahedron is the minimum solid: the fewest faces that can enclose a volume. This paper identifies three structural properties of the tetrahedron that connect biological zinc to the eigenvalue tower of the companion papers. First, the interior measurement: an observer at the centroid sees three distances whose ratios trace a logarithmic spiral with growth factor √3, and whose outer-to-inner ratio R/r = 3 is the unique integer among all Platonic solids. Second, the gap: the inscribed sphere fills only π√3/18 ≈ 30.23% of the tetrahedral volume — the largest observation gap of any Platonic solid. Third, the floor identification: at the 4-cell stage of embryonic development, four blastomeres arrange tetrahedrally, creating a void fraction ≈ 0.2204. Multiplied by the two-term self-consistency value α⁻¹ = 137.035999177, the floor gives ⌊30.198⌋ = 30 = Z(zinc). A second independent path — β⁻¹ × (1 − π√3/18) — also floors to 30. A sixth row in the floor table identifies the proton: the zinc contribution (fill − void ≈ 0.08194) at the deepest eigenvalue level γ⁻¹ floors to 1 = Z(H). The total energy budget partitions into void (22.04%), zinc (8.19%), and photon overshoot (69.77%), with the photon release equalling the tetrahedral observation gap.
Jay Andrew Carpenter (Sun,) studied this question.