TOE - Chaotic geometry discretization (CGD)
TOE - Chaotic geometry discretization (CGD)
In questa prima parte del lavoro si dimostra come la discretizzazione dello spazio-tempo in una maglia (mesh) e la sua viscosità intrinseca permettano alle equazioni di Einstein di rimanere valide nell'infinitamente piccolo, evitando le singolarità matematiche tramite il meccanismo del Salto di Fase. "This first part of the work demonstrates how the discretization of spacetime into a mesh and its intrinsic viscosity allow Einstein’s equations to remain valid at the infinitesimal scale. By introducing the Phase Jump mechanism, the model effectively bypasses mathematical singularities, providing a bridge between General Relativity and discrete chaotic dynamics."
2.32 and 2.39, Feigenbaum and 137, Mesh discretization, Chaotic, Toe trough geometry discretization, Proton Radius, Granular lattice, Infinitesimal scale and Einstein, 24.14 and 137/59
2.32 and 2.39, Feigenbaum and 137, Mesh discretization, Chaotic, Toe trough geometry discretization, Proton Radius, Granular lattice, Infinitesimal scale and Einstein, 24.14 and 137/59
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