What question did this study set out to answer?

The aim is to create a theoretical framework connecting physics with computational concepts to explain cosmic phenomena.

March 19, 2026Open Access

The Computational Ontology of the Universe

Key Points

The aim is to create a theoretical framework connecting physics with computational concepts to explain cosmic phenomena.
Developed a formal derivation of Milgrom’s acceleration in a structured lattice framework.
Analyzed dark energy through the lens of information thermodynamics using Landauer's Principle.
Redefined dark matter in terms of computational viscosity to address galactic dynamics.
Reinterpreted the Einstein Tensor as a Data Flux Tensor in relation to relativistic mechanics.
Proposed atomic stability based on quantum error correction codes and evaluated radioactive decay.
Addressed the Hubble tension by treating cosmic expansion as a network clock-speed variable.
Provided a novel explanation for the Radial Acceleration Relation without invoking dark matter.
Identified potential pathways for room-temperature superconductivity through advanced lattice engineering.
Outlined falsifiable predictions including the finitude of pi at the Planck scale.

Abstract

### **WORK DESCRIPTION** **Title: ** The Computational Ontology of the Universe: A Unified Field Theory **Author: ** Jeferson Monção Brasil This research paper provides a comprehensive theoretical framework for the **Computational Ontology of the Universe (TUC) **. The work is structured into six major thematic parts, bridging the gap between fundamental physics and theoretical computer science: 1. **Macro-Scale Cosmology: ** A formal derivation of Milgrom’s acceleration (a₀) as a function of the Hubble horizon’s surface gravity, distributed across a 2D=6 orthogonal lattice. It addresses the "Hubble Tension" by treating the expansion as a network clock-speed variable. 2. **Information Thermodynamics: ** An analysis of Dark Energy as the thermal cost of vacuum information processing, utilizing Landauer’s Principle to correlate energy density with the bit-erasure limit (2). 3. **Galactic Dynamics: ** A redefinition of Dark Matter as "Computational Viscosity" (), explaining the Radial Acceleration Relation (RAR) without the need for non-baryonic particles. 4. **Stellar and Relativistic Mechanics: ** A reinterpretation of the Einstein Tensor as a Data Flux Tensor, identifying Mercury’s perihelion precession as a byproduct of the 6-neighbor coordination overhead in the spatial mesh. 5. **Microscopic Quantum Logic: ** A proposal for atomic stability based on Quantum Error Correction Codes (QECC). This section redefines radioactive half-life as a Hardware Reliability Rating (MTBF) caused by background noise interference. 6. **Solid State Engineering: ** A roadmap for Room-Temperature Superconductivity (RTSC) through the application of dimensional filtering (2D=2) in twisted bilayer lattices to eliminate lattice-induced latency. The work concludes with a set of falsifiable predictions, including the finitude of at the Planck scale and the expected observations from the James Webb Space Telescope (JWST) regarding early galaxy formation. ---

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