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2026
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| Online-Zugang: | https://doi.org/10.5281/zenodo.18312350 |
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| _version_ | 1866901550106935296 |
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| author | Baker, Steve |
| author_facet | Baker, Steve |
| contents | <h2>Abstract</h2> <p>This working paper synthesizes a geometric framework for particle physics based on a discrete, superfluid<br>vacuum structure. We investigate whether fundamental constants, including the fine structure constant<br>(α) and lepton mass ratios, can be derived from the topological constraints of a 7D phase space with G2<br>holonomy.Key results include a geometric derivation of the Koide formula (Q = 2/3) as a symmetry<br>constraint, a calculation of the fine structure constant (α ≈ 1/137.036) via Weyl tube volume correc-<br>tions, and a predicted mass hierarchy for the neutrino sector.New in Version 2: We extend the framework<br>to macroscopic scales, deriving a mass-dependent decoherence rate (τ ∝ M −2.67 ) arising from non-<br>associative geometric phase errors. This prediction identifies a specific “decoherence cliff” testable by<br>next-generation optomechanics experiments.</p> <h3> </h3> |
| format | Recurso digital |
| id | zenodo_https___doi_org_10_5281_zenodo_18312350 |
| institution | Zenodo |
| language | |
| publishDate | 2026 |
| publisher | Zenodo |
| record_format | zenodo |
| spellingShingle | Geometric Mass Generation and Macroscopic Decoherence (Vol. 2) Baker, Steve <h2>Abstract</h2> <p>This working paper synthesizes a geometric framework for particle physics based on a discrete, superfluid<br>vacuum structure. We investigate whether fundamental constants, including the fine structure constant<br>(α) and lepton mass ratios, can be derived from the topological constraints of a 7D phase space with G2<br>holonomy.Key results include a geometric derivation of the Koide formula (Q = 2/3) as a symmetry<br>constraint, a calculation of the fine structure constant (α ≈ 1/137.036) via Weyl tube volume correc-<br>tions, and a predicted mass hierarchy for the neutrino sector.New in Version 2: We extend the framework<br>to macroscopic scales, deriving a mass-dependent decoherence rate (τ ∝ M −2.67 ) arising from non-<br>associative geometric phase errors. This prediction identifies a specific “decoherence cliff” testable by<br>next-generation optomechanics experiments.</p> <h3> </h3> |
| title | Geometric Mass Generation and Macroscopic Decoherence (Vol. 2) |
| url | https://doi.org/10.5281/zenodo.18312350 |