DUT Structural Core Simulator: Computational Model for Gravitational Nucleus Dynamics in the Dead Universe Theory Framework - v5.0

DUT Quantum Simulator – Technical Overview

The simulator accurately reproduces the stellar mass curves of high-redshift galaxies observed by JWST, such as GLASS-z13, validating the predictive power of the Dead Universe Theory (DUT).

If you are interested in simulating advanced cosmological scenarios using the mathematical core of the DUT framework for academic research or peer-reviewed scientific work, we recommend:

DUT Quantum Simulator v5.0:

The Computational Framework Enabling 180-Billion-Year Cosmological Simulations and Predicting High-Redshift Galaxies (z > 15)

After exploring the DUT Quantum Simulator, researchers are encouraged to deepen their investigation through a second, complementary module:

Access the full General Relativity–based simulation environment — focused on non-singular gravitational dynamics — by downloading the official code here:
Link download  DUT GR 4.0:  https://zenodo.org/records/15843811

Technical Document – Summary

This technical document presents the computational simulator developed for the Dead Universe Theory (DUT), implementing a real-time numerical model that explores the gravitational core of a non-singular structural black hole, fully consistent with General Relativity. The simulator dynamically solves a modified gravitational potential, incorporates entropy gradients, and computes internal acceleration profiles. These formulations are integrated into the DUT Quantum Simulator, enabling thermodynamic stabilization, metric deformation, and gravitational topography simulation across the layered retraction structure of DUT cosmology. Full parameter control is provided, allowing predictive visualization of entropic retraction dynamics governing the gravitational interiors of non-singular black hole models. The platform supports both theoretical exploration and educational demonstration of DUT’s structural framework.

In contrast to traditional models where light and stellar activity define cosmic vitality, DUT proposes a universe born from the ashes of a vast and obscure predecessor, where light emerges not as a constant, but as a rare anomaly. It challenges prevailing paradigms by suggesting that the observable universe—its stars and galaxies—is located at the core of a colossal black hole: the heart of the dead universe. Within this framework, conventional physical laws are interwoven with the arcane rules of a cosmology that no longer exists, yet still deeply shapes the cosmic landscape we observe.

The full predictive framework — including the entropic incorporation of black holes, the derivation of negative spatial curvature (with values around –7%), and its embedded numerical parameters — was originally established and published in earlier foundational studies. The Dead Universe Theory postulates that the observable universe is an entropic anomaly confined within the gravitational well of a primordial structural black hole. This naturally leads to a thermodynamic retraction scenario, explains the asymmetric decline in galaxy formation, predicts the onset of cosmic infertility, and proposes a final cosmological state governed by entropy rather than continuous expansion or collapse.

Simulator Description

The DUT Structural Core Simulator is a standalone computational platform designed to simulate non-singular gravitational cores within the framework of the Dead Universe Theory. It models the internal dynamics of structural black holes — interpreted as thermodynamically stabilized regions rather than singularities — by solving a modified gravitational potential equation and computing entropy gradients and acceleration profiles. This allows researchers to investigate gravitational stratification processes, metric deformation, and entropic retraction at cosmic scales.

Built entirely with HTML5, CSS3, and JavaScript, the simulator operates fully offline, ensuring intellectual sovereignty and reproducibility. It features interactive 1D and 2D visualizations, parameterized inputs, and real-time animated simulations. A Local Scientific Ledger, inspired by blockchain architecture, is integrated to immutably record simulation runs, enabling verifiable audit trails and protecting intellectual property.

Scientific applications include modeling gravitational stabilization, entropy field dynamics, and galaxy formation scenarios at high redshift. The simulator supports both theoretical investigation and educational visualization, serving as the computational backbone of the DUT framework. With future plans to integrate quantum computing, NASA APIs, and zero-knowledge proofs, the DUT Quantum Simulator aims to establish a new paradigm for falsifiable, decentralized, and thermodynamically grounded cosmology.