Gorde:
| Egile nagusia: | |
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| Formatua: | Recurso digital |
| Hizkuntza: | |
| Argitaratua: |
Zenodo
2026
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| Gaiak: | |
| Sarrera elektronikoa: | https://doi.org/10.5281/zenodo.19049066 |
| Etiketak: |
Etiketa erantsi
Etiketarik gabe, Izan zaitez lehena erregistro honi etiketa jartzen!
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Aurkibidea:
- <p><span>This Paper provides the first physical derivation for the Cosmological Constant (</span><span>\bm{\Lambda}</span><span>) by replacing the traditional "vacuum energy" placeholder with a dynamic, closed-loop thermodynamic feedback mechanism. Utilizing the 174-Step Integrated Efficiency Model (IEM), we demonstrate that the energy captured by localized nodes—specifically black hole manifolds—is not lost to the system but is redistributed back to the global field.</span><span> </span></p> <p><span>The Mathematical Foundation:</span></p> <p><span>The paper establishes a mechanical baseline for the energy cycle of the manifold by substituting the static (</span><span>Lambda)</span><span> in the Einstein Field Equations with a dynamic Redistribution Term. This term is governed by two primary constraints:</span><span> </span></p> <p><span>• The 18.03% Displacement Tax (</span><span>tau)</span><span>: A mandatory connectivity tax required for all redistributed energy.</span><span> </span></p> <p><span>• The Primal Invariant (</span><span>psi = 1.22)</span><span>: A scaling factor applied across the 174-step hierarchy of the scalar ladder.</span><span> </span></p> <p><span>The resulting equation provides a deterministic source for the pressure driving accelerating expansion, effectively reconciling the Information Paradox by transforming local matter into global expansion potential.</span></p>