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| Natura: | Recurso digital |
| Lingua: | inglese |
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Zenodo
2026
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| Accesso online: | https://doi.org/10.5281/zenodo.20009592 |
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| _version_ | 1866901827868426240 |
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| author | Tollini, Larry |
| author_facet | Tollini, Larry |
| contents | <p><span>The Hubble tension, a persistent discrepancy between local and early-universe measurements of the cosmic expansion rate, poses a formidable challenge to the standard <span class="math-inline">$\Lambda$</span>CDM model</span><span><sup class="superscript"></sup></span><span>. Here, we demonstrate that this tension is not a signature of new particle physics or exotic dark energy, but a predictable consequence of the universe’s underlying topological manifold</span><span><sup class="superscript"></sup></span><span>. We introduce a framework in which the observed redshift is reinterpreted as a manifestation of an intrinsic geometric gradient, rather than a purely kinematic expansion of space</span><span><sup class="superscript"></sup></span><span>. Our model derives the Hubble discrepancy from first principles, establishing a unified scaling relation that aligns local observations with the cosmic microwave background data</span><span><sup class="superscript"></sup></span><span>. Crucially, we incorporate a natural screening mechanism that recovers general relativity in high-density environments, ensuring full consistency with precise solar-system and galactic tests</span><span><sup class="superscript"></sup></span><span>. This topological approach resolves the Hubble tension without the need for fine-tuned parameters, offering a parsimonious solution with clear, testable predictions for future high-redshift observations</span><span><sup class="superscript"></sup></span><span>.</span></p> |
| format | Recurso digital |
| id | zenodo_https___doi_org_10_5281_zenodo_20009592 |
| institution | Zenodo |
| language | eng |
| publishDate | 2026 |
| publisher | Zenodo |
| record_format | zenodo |
| spellingShingle | A Geometric Manifold Resolution to the Hubble Tension Tollini, Larry Cosmology Hubble tension Geometric Manifold Universal Scaling Equation Dark Energy JWST Redshift <p><span>The Hubble tension, a persistent discrepancy between local and early-universe measurements of the cosmic expansion rate, poses a formidable challenge to the standard <span class="math-inline">$\Lambda$</span>CDM model</span><span><sup class="superscript"></sup></span><span>. Here, we demonstrate that this tension is not a signature of new particle physics or exotic dark energy, but a predictable consequence of the universe’s underlying topological manifold</span><span><sup class="superscript"></sup></span><span>. We introduce a framework in which the observed redshift is reinterpreted as a manifestation of an intrinsic geometric gradient, rather than a purely kinematic expansion of space</span><span><sup class="superscript"></sup></span><span>. Our model derives the Hubble discrepancy from first principles, establishing a unified scaling relation that aligns local observations with the cosmic microwave background data</span><span><sup class="superscript"></sup></span><span>. Crucially, we incorporate a natural screening mechanism that recovers general relativity in high-density environments, ensuring full consistency with precise solar-system and galactic tests</span><span><sup class="superscript"></sup></span><span>. This topological approach resolves the Hubble tension without the need for fine-tuned parameters, offering a parsimonious solution with clear, testable predictions for future high-redshift observations</span><span><sup class="superscript"></sup></span><span>.</span></p> |
| title | A Geometric Manifold Resolution to the Hubble Tension |
| topic | Cosmology Hubble tension Geometric Manifold Universal Scaling Equation Dark Energy JWST Redshift |
| url | https://doi.org/10.5281/zenodo.20009592 |