Independent Theoretical Physicist | Quantum Information Researcher | Codex Alpha Research

Welcome to my main research repository, documenting a multi-year independent research programme at the intersection of theoretical physics, quantum information, emergent spacetime, computational analysis, and unified field theory.

This repository serves as a public hub for my work on Codex Alpha, including its theoretical manuscripts, computational framework, research outputs, and related scientific developments.

A theoretical framework exploring an informational extension of General Relativity and Quantum Mechanics

Codex Alpha proposes a unified theoretical framework in which spacetime geometry is interpreted as an emergent structure arising from an underlying coherent informational substrate called the Telascura.

At the core of the model is the coherence-gradient structure represented by:

G_{μν} + Λg_{μν} = (8πG / c4) ⟨ T̂_{μν} ⟩_{∇K}

In this formulation, the right-hand side is interpreted as a coherence-weighted energy-momentum response, where the local informational coherence gradient ∇K controls deviations from the standard geometric-matter coupling of General Relativity.

A Variational Derivation of an Informational Extension of Einstein Field Equations

DOI: 10.5281/zenodo.20355167
Repository: foundations-of-codex-alpha-dynamics

This manuscript provides the minimal variational foundation of the effective continuous sector of Codex Alpha. It derives the informational extension of Einstein field equations from an explicit action principle involving the spacetime metric, a scalar coherence field, ordinary matter fields, and a coherence-weighted Schwinger functional.

Main contributions:

• Explicit variational derivation of the Codex Alpha dynamical core
• Definition of the effective continuous sector of the Telascura
• Dimensional consistency and minimality of the scalar coherence extension
• Recovery of General Relativity in the uniform-coherence limit
• Absence of Ostrogradsky ghosts in the minimal sector
• Falsifiability through cosmological perturbations, gravitational waves, gravitational lensing, and post-Newtonian regimes

Informational Unification of General Relativity and Quantum Mechanics

DOI: 10.5281/zenodo.17074972

Codex Alpha 3.0 is the complete theoretical architecture of the project. It develops the broader framework of the Telascura, nodal informational structures, emergent spacetime, retrocausal operators, coherence dynamics, and the extended informational ontology of the theory.

Research role:

Codex Alpha 3.0 — Iconoclast Edition
= full theoretical architecture
Foundations of Codex Alpha Dynamics
= minimal variational derivation of the effective continuous sector

DOI: 10.5281/zenodo.20335018

The Codex Alpha Computational Framework is a modular research infrastructure designed to support the computational and data-oriented side of the Codex Alpha programme.

It provides a structured environment for AI-assisted analysis of large-scale cosmological structures, anomaly detection, graph-based modeling, interpretability, ranking, and exploratory validation of candidate coherence signatures.

Core objectives:

• AI-assisted analysis of large-scale cosmological datasets
• Detection of anomalous astrophysical patterns
• Graph-based modeling of correlations between astronomical sources
• Ranking and prioritization of candidate targets
• Exploratory validation workflows connected to Codex Alpha predictions
• Preparation of future computational pipelines for observational testing

Foundations of Codex Alpha Dynamics is the formal mathematical companion manuscript to Codex Alpha 3.0.

Its purpose is not to expand the theory with additional phenomenological claims, but to isolate and derive the minimal mathematical core of the effective continuous dynamics.

The manuscript focuses on the regime in which the underlying discrete informational structure of the Telascura can be approximated by a smooth Lorentzian manifold.

Central equation:

G_{μν} + Λg_{μν} = (8πG / c4) ⟨ T̂_{μν} ⟩_{∇K}

Here, the right-hand side is defined as the metric response of a coherence-weighted functional measure rather than introduced phenomenologically.

Key features:

• Variational action principle
• Coherence scalar field K
• Coherence-weighted Schwinger functional W[g, ∇K]
• Effective continuous approximation of the Telascura
• Recovery of General Relativity when ∇K → 0
• Explicit domain of perturbative validity
• Absence of Ostrogradsky ghosts in the minimal continuous sector
• Possible observational deviations in gravitational and cosmological regimes

The Codex Alpha Computational Framework is the computational research layer of the Codex Alpha project.

While the theoretical manuscripts establish the formal structure of the model, the computational framework is designed to support exploratory analysis, data organization, anomaly detection, graph modeling, and future comparison with observational datasets.

Current development focus:

• Framework architecture
• Dataset organization
• Candidate ranking
• Anomaly detection
• Graph-based modeling
• Interpretability modules
• Exploratory cosmological workflows
• AI-assisted analysis pipelines

The framework is not intended to replace theoretical derivation. It serves as a bridge between formal predictions and future testable data-driven investigations.

Science outreach project translating foundational questions into accessible narrative essays

Frontiers of Reality is a parallel outreach and publishing project connected to Codex Alpha Research.
Its purpose is to build a bridge between advanced theoretical work and a wider public interested in physics, cosmology, time, matter, information, emergence, and the changing scientific image of reality.

The series does not replace the technical Codex Alpha manuscripts. It develops a more readable conceptual path for readers who want to approach contemporary physics without starting from formal equations, while preserving the core research identity of the project: rigor, intellectual honesty, scientific imagination, and the investigation of reality as an informational and emergent structure.

Work completed:

• Defined the editorial architecture of the Frontiers of Reality series
• Developed the conceptual framework connecting modern physics, information, emergence, and scientific philosophy
• Published the opening volumes of the series in English and Italian editions
• Integrated the series into the broader Codex Alpha public research ecosystem
• Created dedicated website sections and book pages for long-term discoverability
• Established a public outreach layer complementary to the technical research manuscripts

Available books:

• The Universe Is Not a Machine — Amazon Paperback
• Time Is Not a River — Amazon Paperback · Kindle

Quantum computing architecture based on multidimensional symbolic geometry

QIM METATRON is a quantum informational architecture exploring the integration of Metatron’s Cube, tesseract structures, symbolic-topological computation, and coherent multidimensional information processing.

Conceptual elements:

• Metatron Cube-inspired node architecture
• Tesseract-enhanced quantum structures
• Symbolic-topological processing
• Quantum information organization
• Exploratory consciousness-machine interface models

Research role:

QIM METATRON represents a speculative but structured exploration of how symbolic geometry, quantum logic, and informational coherence may converge in future computational architectures.

Exploratory work on 5D geometric frameworks and fundamental physics problems

This research line includes collaborative work with Louis-François Claro on extended geometric frameworks involving Higgs torsion, negative mass structures, Navier–Stokes, Yang–Mills, cosmology, and N-body dynamics.

1. Yang–Mills Mass Gap Resolution
   DOI: 10.5281/zenodo.16168587

2. Hybrid Cosmology + N-Body + Navier–Stokes
   DOI: 10.5281/zenodo.16153428

3. Complete Navier–Stokes Solution
   DOI: 10.5281/zenodo.16039574

4. Gravitational N-Body Problem in 5D
   DOI: 10.5281/zenodo.15874407

These works are exploratory and are part of a broader collaborative research programme on high-dimensional geometric approaches to fundamental physical systems.

• Informational extensions of gravitational dynamics
• Emergent spacetime models
• Variational principles
• Scalar coherence fields
• Effective field theory reasoning
• Coherence gradients ∇K
• Continuous limits of discrete informational networks
• Recovery of standard General Relativity and quantum-field-theoretic limits

• AI-assisted data analysis
• Graph-based modeling
• Cosmological dataset exploration
• Anomaly detection
• Ranking and interpretability pipelines
• Numerical prototyping
• Future validation against astronomical and cosmological datasets

Codex Alpha identifies possible falsifiable deviations in:

• Cosmological perturbations
• Gravitational-wave propagation
• Gravitational lensing
• Post-Newtonian regimes
• Astrophysical coherence signatures
• Large-scale structure anomalies

• ORCID: 0009-0008-2253-7008
• GitHub: github.com/Miriadenera
• Website: codexalpha.org

• Open research manuscripts on Zenodo
• Independent theoretical physics publications
• Computational research framework
• GitHub repositories for public research dissemination
• Cross-disciplinary work on quantum information, emergent spacetime, and computational cosmology
• Popular science outreach through the Frontiers of Reality series

• 🧠 GitHub: github.com/Miriadenera
• 📐 Foundations Repository: foundations-of-codex-alpha-dynamics
• 🌐 Website: www.codexalpha.org
• 📚 Frontiers of Reality — Amazon: The Universe Is Not a Machine · Time Is Not a River
• 📄 Foundations DOI: 10.5281/zenodo.20355167
• 🧮 Computational Framework DOI: 10.5281/zenodo.20335018

• 🔗 LinkedIn: davide-cadelano-5b68a936a
• 🐦 X: @QIM_METATRON
• 📘 Facebook: Research Profile

• 🏛️ Institutional email: davide.cadelano@codexalpha.org

📁 codex-alpha/
├── 📄 manuscripts/ # Complete theoretical manuscripts
├── 📐 foundations/ # Minimal variational foundations of Codex Alpha
├── 🧮 computational/ # Computational framework and analysis tools
├── 🧠 qim-metatron/ # Quantum informational architecture
├── 🤝 collaborations/ # Collaborative research with external authors
├── 📊 visualizations/ # 3D/4D rendering and conceptual visualizations
├── 📚 publications/ # Papers, preprints, Zenodo releases and citation files
├── 📖 outreach/ # Frontiers of Reality popular science and public-facing materials
└── 🔬 experimental/ # Testable predictions, protocols and observational directions

@misc{Cadelano2026Foundations,
 author = {Cadelano, Davide},
 title = {Foundations of Codex Alpha Dynamics: A Variational Derivation of an Informational Extension of Einstein Field Equations},
 year = {2026},
 publisher = {Zenodo},
 version = {1.0},
 doi = {10.5281/zenodo.20355167},
 url = {https://doi.org/10.5281/zenodo.20355167}
}

@misc{Cadelano2026ComputationalFramework,
 author = {Cadelano, Davide},
 title = {Codex Alpha Computational Framework},
 year = {2026},
 publisher = {Zenodo},
 version = {0.1.0},
 doi = {10.5281/zenodo.20335018},
 url = {https://doi.org/10.5281/zenodo.20335018}
}

@misc{Cadelano2025Iconoclast,
 author = {Cadelano, Davide},
 title = {Codex Alpha -- Unified Theory between General Relativity and Quantum Mechanics ICONOCLAST},
 year = {2025},
 publisher = {Zenodo},
 version = {3.0},
 doi = {10.5281/zenodo.17074972},
 url = {https://doi.org/10.5281/zenodo.17074972}
}

The future of physics may require a deeper synthesis between geometry, information, computation, and observation.

Codex Alpha is not presented as a final statement, but as a structured research programme: a framework intended to be examined, refined, challenged, and tested.

Its central objective is to investigate whether spacetime, gravitation, and quantum phenomena can be understood as different effective manifestations of a deeper informational coherence structure.

The coherence gradient ∇K represents the symbolic and mathematical node through which this programme is developed.

All public research material in this repository is released under:

Creative Commons Attribution 4.0 International License (CC BY 4.0)

Unless otherwise stated, you are free to share and adapt the material with appropriate attribution.