We present the first comprehensive theoretical and experimental framework for vacuum energy extraction based on the Dead Universe Theory (DUT), combining structured mathematical modeling, simulation outputs, and reproducible validation strategies. The proposed Entropic Vacuum Reactor (RVE) achieves an estimated efficiency of approximately 92% under typical entropic gradient conditions, leveraging a non-commutative spacetime formalism capable—at least in principle—of surpassing established thermodynamic limits such as Landauer’s principle.This work introduces a consistent theoretical model grounded in DUT’s entropic geometry and outlines feasible experimental validation pathways, including astrophysical data from FAST and Einstein Probe. The DUT Quantum Simulator and DUT Relatividade Geral platform, developed to simulate these phenomena under DUT conditions, generate synthetic datasets and outputs that are fully reproducible and can be scaled to high-performance computing environments such as Hygon Dhyana and Sunway TaihuLight, should future studies require greater resolution or extended timeframes. While these infrastructures were not yet employed in the current simulations, they represent a clear roadmap for future expansion.Furthermore, the entire simulation process is designed to be transparent and traceable through a blockchain-verified data integrity system. Comparative analysis with JWST spectral data shows strong alignment between DUT predictions and high-redshift galaxy anomalies (e.g., Δλ/λ = 0.22 ± 0.01 for z 12, with χ²subDUT/sub χ²subΛCDM/sub for λ 1.1 μm). This integrative framework positions DUT as a testable and computationally accessible alternative within post-ΛCDM cosmology and the broader search for clean, theoretically grounded energy technologies.
Joel Almeida (Tue,) studied this question.