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| Format: | Recurso digital |
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Zenodo
2026
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| Online Access: | https://doi.org/10.5281/zenodo.18917144 |
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Table of Contents:
- <p><span>The persistent discrepancy between early-universe and late-universe measurements of the Hubble constant (H0) represents a fundamental structural tension within the ΛCDM cosmological model. We propose that this discrepancy is not a uniformly accelerated metric expansion, but a dual regime observational artifact arising from the embedding of the observable universe within an 11-dimensional topological manifold. By modeling spacetime as a 4-dimensional boundary (3S +1T1) projecting from an extended bulk containing 6 unprojected spatial dimensions and a secondary temporal axis (6S + 1T2), we isolate mass-anchored metric expansion from massless photon propagation. Utilizing the geometric topology of Poincaré Dodecahedral Space (PDS), we define a quantized topological phase sheer of π/12 radians across the bulk. For baryonic mass, the true local metric expansion is derived as 69.8 km/s/Mpc, rigidly consistent with TRGB and BAO constraints. For massless wavefunctions, the π/12 bulk geometry acts as a refractive index, inducing an anomalous cosmological redshift. Calculating the null geodesic through the 11D metric tensor yields a false observed acceleration of 72.26 km/s/Mpc for local photonic phenomena, preserving local Lorentz invariance. We resolve the requisite Two-Time (2T) vacuum instability by demonstrating that the π/12 boundary condition acts as a topological invariant enforcing an Sp(2,R) gauge symmetry. This yields a ghost-free Lagrangian action that unifies the Hubble Tension and the neutrino mass hierarchy via chiral symmetry breaking.</span></p>