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Published January 25, 2026 | Version v2
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𝑎(𝑡 →0)≠0 in the GID Architecture: Resolution of Temporal and Spatial Singularities through Overcoming the Spacetime Continuum as Causal Agent of Divergences

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General Relativity exhibits asymptotic divergences in singular regimes [a(t → 0) = 0, r → 0], identifying the spacetime continuum as the direct causal agent of these pathologies. This work formalizes the Global Inhomogeneity Domains (GID) framework, establishing a self-supporting architecture where the basal domain D₀ (Φ₀) constitutes the minimal finite infrastructure [a(t → 0) = Φ₀ ≠ 0] upon which domains D₁ and D₂ emerge as coupled self-consistent solutions.
Under this paradigm, the speed of light is not a metric prohibition (Friedmann pathology), but the maximum structural flow capacity defined by the basal gradient: c = |∇Φ₀|. Potential-Induced Dispersion (universal Shapiro effect) provides empirical verification of photon deceleration in gradients. The model resolves the Hubble Tension (35 km/s/Mpc dipole) and explains JWST-observed galactic maturity (z ≥ 14) through structural progenitors and directed baryogenesis.
 

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  • [1] JADES Collaboration. (2024). The JADES Survey: Discovery and Characterization of Massive Galaxies at 𝑧 > 14 with JWST. Nature Astronomy, 8, 112–124. Link to JADES/JWST. 5 [2] Euclid Collaboration. (2026). Euclid Early Data Release: Constraints on Cosmological Anisotropies and the Dipolar Nature of the Hubble Tension. Astronomy & Astrophysics, SpecialIssue Jan 2026.ESA Euclid Mission. [3] Riess, A. G., et al. (2025). A 5𝜎 Divergence in the Hubble Constant: Evidence for New Physicsinthe Local Flow.TheAstrophysical Journal Letters,980(L2). [4] Shapiro, I. I. (1964). Fourth Test of General Relativity. Physical Review Letters, 13(26), 789–791. [5] Magueijo,J.,&Moffat,J.W.(2025).VaryingSpeedofLightasaSolutiontotheHorizon ProblemwithoutInflationary Fine-Tuning. General RelativityandGravitation,57(1). [6] Planck Collaboration. (2020). Planck 2018 results. VI. Cosmological parameters. Astron- omy&Astrophysics,641,A6. [7] Anderson, J. D., et al. (2002). Study of the anomalous acceleration of Pioneer 10 and 11. PhysicalReviewD,65,082004. [8] Mariscal-Estrada, J. (2026a). Phenomenological Evidence for Three Horizon-Scale Co- herentEnergyRegionsandCosmicAnisotropy.Zenodo.DOI:10.5281/zenodo.18328984. [9] Mariscal-Estrada, J. (2026b). Dynamic Interaction of Global Inhomogeneity Domains and Emergence of Observable Cosmological Geometry. Zenodo. DOI: 10.5281/zen- odo.18329112. [10] Mariscal-Estrada, J. (2026c). Supercluster Formation Dynamics within Global Inhomo- geneityDomains Framework.Zenodo.DOI: 10.5281/zenodo.18329232. [11] Mariscal-Estrada,J.(2026d).GlobalGeometricArchitectureTheory(GIDTheory): Foun- dationalGIDLaws.Zenodo.DOI: 10.5281/zenodo.18329340. [12] Mariscal-Estrada, J. (2026). The Global Universe: Evidence, Dynamics, and Geometric Law (GIDFramework).Zenodo.DOI: 10.5281/zenodo.18336073.