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| Format: | Recurso digital |
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| Udgivet: |
Zenodo
2026
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| Online adgang: | https://doi.org/10.5281/zenodo.20296799 |
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Indholdsfortegnelse:
- <p>We investigate how certain closed structures of compact phase coherence may collectively acquire effective properties traditionally associated with electronic structures. Building on our previous works on spinorial Möbius-type geometries, non-factorizable collective minima, and emergent coherence redistributions, we examine how global topological constraints imposed on a compact phase may produce stable closed configurations possessing internal circulations, persistent topological invariants, and irreducible collective energetic costs.</p> <p>In this framework, electronic-like structures are no longer interpreted as primitive independent entities. They emerge as collective self-organized configurations associated with the global compatibility constraints imposed on compact phase coherence.</p> <p>We show that several formal properties commonly associated with fermionic structures — including effective spinorial behavior, persistent internal circulation, topological robustness, and collective stability — may arise from globally constrained closed coherence structures.</p> <p>The approach remains intentionally minimal, exploratory, and heuristic. It does not attempt to reconstruct the complete quantitative formalism of the physical electron, but rather to investigate whether some of its effective structural properties may emerge from a minimal topological dynamics of compact phase coherence.</p>