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| Format: | Recurso digital |
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| Udgivet: |
Zenodo
2026
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| Fag: | |
| Online adgang: | https://doi.org/10.5281/zenodo.19962633 |
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Indholdsfortegnelse:
- <p>Abstract<br>We present a unified informational-connectivity framework referred to<br>as the Space-Field-Gravity (PPG) model, in which spacetime geometry,<br>gravitation, and temporal evolution emerge from the dynamics of an underlying<br>informational medium. The model introduces the Guse-Guseva<br>Principle of dynamic stabilization, according to which the field continuously<br>evolves toward maximal connectivity homogeneity while never fully<br>reaching equilibrium due to persistent matter-induced excitations.<br>We show that the resulting scale-dependent effective gravity naturally<br>modifies cosmological structure formation without requiring conventional<br>cold dark matter particles or a cosmological constant as fundamental substances.<br>The model is implemented numerically through a modified version<br>of CLASS coupled to MontePython.<br>A preliminary likelihood analysis using CMB, BAO, and growth-rate<br>data demonstrates that the PPG framework can reproduce large-scale<br>cosmological observations while simultaneously enhancing early structure<br>formation. In particular, the model significantly improves agreement with<br>the observed abundance of high-redshift quasars detected by SDSS and<br>JWST.<br>The framework further provides a unified informational interpretation<br>of dark matter, dark energy, gravitational time dilation, and cyclic cosmological<br>evolution.</p>