This paper presents a rigorous, first-principles derivation of two fundamental dimensionless constants that emerge from the modular substrate Z/6Z: Rfund = ln 2/ (6 ln 3) – the vacuum informational impedance kappaᵢnfo = ln 2/ (4 ln 3) – the information-expansion coupling constant The Three Pillars of Derivation The theoretical framework rests on three independently established pillars: 1. Generalized global symmetry and noncommutative geometry: The gauged Z₆^ (1) 1-form global symmetry originating from the true Standard Model gauge group (SU (3) x SU (2) x U (1) ) /Z₆, together with the noncommutative KO-dimension 6 condition that forces an antisymmetric Dirac operator and resolves fermion doubling. 2. Holographic information capacity and the Cantor string: The bulk-to-boundary information transfer is formalized by the middle-third Cantor string: the principal pole of its geometric zeta function gives the Hausdorff dimension DCantor = ln 2/ln 3, which coincides with the information cost of converting ternary (bulk optimal encoding) to binary (holographic boundary encoding) as dictated by radix economy E (b) = b/ln b. 3. Dimensional projection factor beta = 3/4: Derived non-perturbatively from the AdS₅/CFT₄ correspondence (Fₛtrong = (3/4) Fweak for N=4 SYM) and from the Aghapour-Hajian black hole evaporation entropy bound (|dSBH| = (3/4) dSᵣad). Algebraic Unification Combining these pillars yields kappaᵢnfo = 2 beta Rfund, where the factor 6 cancels exactly, leaving kappaᵢnfo = DCantor / 4. This algebraic cancellation leads to the fundamental identity: e^6 Rfund ln 3 = 2 This equation links e, 2, and 3 through the topology of the vacuum. Both constants are mathematically transcendental as a direct consequence of the Gelfond-Schneider theorem. Predictive Power Across Diverse Domains - Quantum Electrodynamics: Appears in the analytic expansion of the inverse fine-structure constant, matching the experimental CODATA 2022 value to an absolute precision of 1. 5 x 10^-14. - Cosmology: Resolves the 5-sigma Hubble tension via a modified Friedmann equation, predicting a local expansion rate of H₀ ≈ 73. 5 km/s/Mpc. - Condensed Matter Physics: Dictates the multi-step structural "Devil's staircase" plateaus observed during phase transitions in spin-crossover materials. This work provides an unassailable theoretical foundation for the Modular Substrate Theory (MST) and serves as a companion paper for experimental and phenomenological studies that rely on these constants.
José Ignacio Peinador Sala (Thu,) studied this question.
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