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| Formato: | Recurso digital |
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Zenodo
2026
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| Acceso en línea: | https://doi.org/10.5281/zenodo.19665294 |
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- <p><strong>Abstract:</strong></p> <p>This work presents the foundational principles of the <strong>Laminar Universe Theory (TUL)</strong>, an alternative physical model proposing a universal continuous medium (the <strong>Plenum</strong>) as the fundamental constituent of reality, replacing the ontology of the geometric vacuum. TUL employs continuum mechanics and topological field theory to derive fundamental constants and physical phenomena.</p> <p>At the microphysical level, elementary particles are modeled as stable, low-energy topological configurations of the medium (<strong>hopfions</strong>). It is demonstrated how emergent mass, spin-1/2, and electric charge arise naturally as phase and chirality properties of these topological defects, providing a geometric interpretation for the fine-structure constant (<span class="math-inline">$\alpha$</span>).</p> <p>On a macroscopic scale, TUL reinterprets gravity not as metric curvature, but as a redistribution of mechanical stresses within the Plenum. Furthermore, it addresses the problem of cosmic expansion through a <strong>dissipative cosmology</strong>, where redshift is derived from the cumulative energy loss of transverse waves propagating through a medium with finite viscosity.</p> <p>The model is formalized via a <strong>Lagrangian formulation</strong> and an extended Navier-Cauchy dynamic equation:</p> <div> <div class="math-block">$$\rho_P \ddot u_i = \partial_j \sigma_{ij} + \eta_P \nabla^2 \dot u_i + f_i^{(\mathrm{top})}$$</div> </div> <p>The potential of the model to fit Type Ia supernova observational data through a dissipation evolution parameter (<span class="math-inline">$\beta$</span>) is discussed, offering a parsimonious alternative to Dark Energy. The paper concludes with a roadmap for the numerical and experimental validation of TUL against General Relativity and the <span class="math-inline">$\Lambda$</span>CDM framework.</p> <p><strong>Keywords:</strong> Continuum Mechanics, Hopfions, Dissipative Cosmology, Redshift, Laminar Universe Theory, Physical Topology, Plenum.</p> <p> </p>