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| Format: | Recurso digital |
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Zenodo
2026
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| Accès en ligne: | https://doi.org/10.5281/zenodo.19019845 |
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- <p>This paper expands the Volumetric Coupling Hypothesis to the macroscopic and cosmological scales, proposing that cosmic expansion is a localized, dynamic thermodynamic process driven by supermassive black holes, rather than a uniform "Dark Energy." By establishing a dual-force environment governed by an inward gravitational vector (1/R²) and an outward volumetric generation vector (1/R), we define an Equilibrium Radius that mechanically resolves the local binding of galaxy clusters against the backdrop of Hubble expansion. Furthermore, we apply this framework to large-scale topological structures, demonstrating that the 1/R expansion naturally produces cosmic voids, which in turn compress ambient matter into the 1/R²-dominated filaments and nodes of the Cosmic Web. The model resolves the James Webb Space Telescope (JWST) early-galaxy tension by framing supermassive black holes as un-transitioned primordial remnants of a supercritical phase transition, and eliminates the need for non-baryonic Dark Matter by re-contextualizing flat galactic rotation curves as standard inertial mechanics within a dynamic, flowing spatial gradient.</p>