DUT Structural Core Simulator: Computational Model for Gravitational Nucleus Dynamics in the Dead Universe Theory Framework - v1.0

Este documento técnico apresenta o simulador computacional desenvolvido para a Teoria do Universo Morto (DUT), implementando um modelo numérico em tempo real que explora o núcleo gravitacional de um buraco negro estrutural sem singularidade, totalmente consistente com a Relatividade Geral. O simulador resolve dinamicamente o potencial gravitacional modificado (Φ = β·e^(–α·r)·cos(κ·r)), incorpora gradientes de entropia (∇S = –(∂Φ/∂r)·ρ(r)) e calcula o perfil de aceleração interna (a(r) = –G·M(r)/r² + ∂Φ/∂r). Essas formulações são integradas ao código DarkStructSim™, simulando estabilização termodinâmica, deformação métrica e topografia gravitacional através das camadas de retração da cosmologia DUT. O simulador permite controle total de parâmetros, oferecendo visualização preditiva da dinâmica de retração entrópica que governa o interior gravitacional de modelos de buracos negros não singulares, e fornece exploração teórica e demonstração educacional da estrutura estrutural do DUT.

Unlike traditional models where light and stellar activity define cosmic vitality, this theory presents a universe born from the ashes of a vast and dark predecessor, where light appears not as a constant, but as a rare anomaly. It challenges prevailing paradigms by proposing that the observable universe, with its stars and galaxies, resides in the core of a colossal black hole — the heart of the dead universe — where the conventional laws of physics intertwine with the arcane rules of a universe that no longer exists but still profoundly influences the cosmic landscape we observe.

This entire predictive framework — encompassing the entropic black hole embedding, the negative curvature derivation, the Ωₖ = −0.07 ± 0.02 value, and the embedded numerical figures — was originally established and published in prior foundational work. The Dead Universe Theory (DUT) predicts that the observable universe is a confined entropic anomaly embedded within the gravitational well of a primordial structural black hole. This model naturally leads to a thermodynamic retraction scenario, explains the asymmetric decline of galactic formation, forecasts the eventual cosmic infertility, and proposes computational simulations for entropy growth, energy depletion, and matter segregation across multiple gravitational layers.