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| Format: | Recurso digital |
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Zenodo
2026
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| Online Access: | https://doi.org/10.5281/zenodo.19026253 |
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Table of Contents:
- <p>The Space-Phase (SP3) framework proposes that physical space behaves as a nonlinear,<br>conditionable medium capable of storing energy, transmitting energy, and retaining<br>structural conditioning from the passage of matter and energy. Reaction–diffusion<br>dynamics within this medium are proposed to produce node–corridor architectures that<br>guide energy transport across physical scales.<br>While many features of SP3 resemble pattern formation observed in nonlinear systems, the<br>theory introduces additional properties not typically included in conventional physical<br>models. These include medium conditioning, corridor reinforcement through historical<br>activity, and guidance gradients that influence subsequent energy or matter flow.<br>To evaluate the scientific viability of SP3, it is necessary to identify empirical tests capable<br>of distinguishing SP3 predictions from those of conventional physics. This paper presents<br>ten measurable discriminators across multiple domains including aviation observations,<br>plasma physics, astrophysical structures, and laboratory pattern-formation experiments.<br>These discriminators provide a structured testing program capable of evaluating whether a<br>conditionable space-phase medium contributes to the organization of physical systems.</p>