What question did this study set out to answer?

The research aims to explore the geometric constraints of an excluded-volume parameter in three dimensions using the Kepler packing theorem.

March 16, 2026Open Access

A Geometric Consistency Bound for the Exclusion Parameter Π = 1/4 in ℝ³: Admissibility under the Kepler Void Fraction

Key Points

The research aims to explore the geometric constraints of an excluded-volume parameter in three dimensions using the Kepler packing theorem.
Utilized the Kepler packing theorem to establish a void fraction ceiling.
Defined an admissibility condition where the exclusion parameter must be less than or equal to the void fraction.
Developed a model for the dimensional family of exclusion parameters.
Identified that 1/4 is the largest admissible unit fraction below the Kepler void ceiling.
Confirmed that 1/3 does not meet the admissibility criteria.
Established a limited geometric consistency bound specific to three dimensions.

Abstract

We study a limited geometric consistency question for an effective excluded-volume parameter Π in three spatial dimensions. Using the Kepler packing theorem (proved by Hales), we take the complementary void fraction vᵥoid = 1 - π/ (3√2) ≈ 0. 25952 as a geometric ceiling under a packed-sphere substrate interpretation. We then adopt the model-dependent admissibility condition Π ≤ vᵥoid, where Π is treated as a coarse-grained effective exclusion parameter rather than the geometric porosity itself. A companion closure proposes the dimensional family Π (D) = 1/ (D+1), whose three-dimensional member is Π (3) = 1/4. Restricting attention to the associated unit-fraction family, we show that 1/4 is the largest admissible unit fraction below the Kepler void ceiling, whereas 1/3 is not. The result is conditional and does not derive Π=1/4 from packing theory alone; it establishes a limited geometric consistency bound for the three-dimensional case.

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