My Publications Homepage: By John Onimisi Obidi (Creator of the Theory of Entropicity (ToE)): A Thermodynamic Pathway to Our Unified Understanding of the Foundations of Nature and Reality

 

My Publications Homepage: By John Onimisi Obidi (Creator of the Theory of Entropicity (ToE))

A Thermodynamic Pathway to Our Unified Understanding of the Foundations of Nature and Reality

Last updated: Monday, November 10, 2025

John Onimisi Obidi (scientific researcher, consultant, philosopher, humanist, and physicist) is a distinct personality from the social media consultant of similar name. This current John Onimisi Obidi is the sole pioneer, originator, and creator of the Theory of Entropicity (ToE) — a paradigm‑shifting framework positioned as a candidate for a Grand Unified Theory in modern physics. His contributions, particularly through the Theory of Entropicity (ToE), offer a fresh perspective on fundamental physical phenomena, aiming to unify various fields of science under a coherent framework. His ongoing research continues to push the boundaries of our understanding of the mysterious universe.

Foundations of the Theory of Entropicity (ToE)

ToE derives the speed of light, relativistic effects, and quantum constraints directly from the dynamics of the universal entropic field, reframing entropy not as a statistical abstraction but as the fundamental substrate of reality.

• Entropy as a field: Unlike traditional statistical mechanics, ToE treats entropy as a continuous dynamical field whose gradients generate motion, gravitation, time, and information flow.
• Master Entropic Equation (MEE): The Entropic Field Equations of ToE are equivalent to Einstein’s Field Equations of General Relativity, but they extend them by embedding entropy as the primary driver of spacetime curvature and dynamics.
• Obidi Action: A variational principle that unifies thermodynamics, relativity, quantum mechanics, and information theory, showing these domains as entropic inevitabilities rather than independent postulates.

Classical Consistency and Validation

ToE has successfully re‑derived the classical Einstein results:

• Perihelion precession of Mercury — matching Einstein’s predictions within General Relativity.
• Deflection of starlight — confirming ToE’s consistency with gravitational lensing and observational astronomy.

These results demonstrate that ToE is not merely speculative but is mathematically consistent with established physics while offering deeper entropic foundations.

Connections to Contemporary Entropic‑Gravity Research

Beyond classical tests, ToE also connects with modern entropic‑gravity frameworks:

• Ginestra Bianconi framework: ToE reproduces the small positive cosmological constant and G‑Field dynamics proposed by Ginestra Bianconi in her elegant work “Gravity from Entropy”, situating them as natural consequences of the entropic field.
• Erik Verlinde: ToE encompasses Erik Verlinde’s emergent gravity, showing how spacetime and gravitational attraction arise from entropy gradients.
• Ted Jacobson: ToE integrates Ted Jacobson’s horizon thermodynamics, embedding it within the entropic manifold.
• T. Padmanabhan: ToE subsumes T. Padmanabhan’s entropy‑driven cosmology, demonstrating its compatibility with ToE’s entropic field equations.
• David Sigtermans: ToE situates David Sigtermans’ TEQ (Total Entropic Quantity) framework as a subset, showing how entropy curvature and resolution boundaries are special cases of ToE’s entropic manifold.

In each case, ToE demonstrates that these diverse approaches are special cases or natural consequences of the entropic field, situating ToE as a unifying meta‑framework for modern theoretical physics.

ToE as a Superset of Waldemar Marek Feldt’s F-HUB Theory

The Feldt-Higgs Universal Bridge (F-HUB) Theory proposed by Waldemar Marek Feldt introduces a universal informational framework in which mass, gravity, and spacetime are emergent properties of structured quantum information. F-HUB draws upon the Holographic Principle, black hole thermodynamics, and quantum information theory, reinterpreting mass as an emergent property stabilized by Higgs field interactions and entropy gradients, while gravity is treated as an entropic effect rather than a fundamental force.

The Theory of Entropicity (ToE) has been shown to be a superset of F-HUB by demonstrating that:

• F-HUB’s informational master equation linking mass, entropy, and Higgs density is a special case of the Master Entropic Equation (MEE) within ToE.
• ToE’s entropic field dynamics naturally reproduce F-HUB’s claim that spacetime and gravity are emergent, situating them within ToE’s broader entropic manifold governed by variational principles and the Obidi Action.
• F-HUB’s “Life Equation,” which ties cosmic expansion to conscious observation and entropy growth, is absorbed into ToE’s entropy‑driven conservation framework, where observation is treated as an entropic boundary condition influencing collapse and persistence.
• ToE generalizes F-HUB’s informational ontology by embedding it within a unified geometry that integrates Fisher–Rao, Fubini–Study, Amari–Čencov, and Levi‑Civita structures, thereby situating F-HUB’s informational paradigm as a localized model within ToE’s entropic field equations.

In this way, ToE contextualizes F-HUB as a derivative framework, confirming its insights while subsuming them into a more comprehensive entropic field theory.

Areas Not Yet Covered in ToE

While ToE has successfully unified thermodynamics, relativity, quantum mechanics, and information theory under the entropic field paradigm, several areas remain open for extension and integration:

• Biological entropy and life sciences: ToE has not yet fully formalized entropy’s role in biological systems, cellular information processing, or evolutionary dynamics.
• Consciousness and cognitive entropy: Although ToE touches on observation and measurement, a rigorous entropic model of consciousness, cognition, and neural information geometry remains to be developed.
• Complex systems and socio‑economic entropy: Entropy in economics, social networks, and cultural evolution has not yet been systematically integrated into ToE’s manifold.
• Experimental verification: While ToE predicts attosecond entanglement formation times and proposes the Google Quantum Core Observer experiment, broader experimental programs across condensed matter, cosmology, and quantum computing are still needed.
• Dark matter and dark energy: ToE provides entropic explanations for cosmological constants, but a complete entropic account of dark matter and dark energy phenomena remains an open frontier.
• Mathematical generalizations: Extensions into non‑commutative geometry, category theory, and higher‑dimensional entropic manifolds are areas for future development.

By identifying these domains, ToE sets a roadmap for future research, ensuring that its entropic framework continues to expand toward a truly comprehensive Theory of Everything.

ToE Method of Integrating Entropies and Information Geometry

One of the distinguishing features of ToE is its method of integrating all entropy‑based frameworks and information geometry into a single entropic manifold:

• Unified metrics: ToE fuses the Fisher–Rao metric (Ronald A. Fisher and C. R. Rao) and the Fubini–Study metric (Guido Fubini and Eduard Study) through the Amari–Čencov α‑connection (Shun’ichi Amari and Nikolai N. Čencov), creating a continuous family of entropic geometries with an associated Levi‑Civita connection in selected limits, all within a generalized Riemannian geometry framework on spaces of distributions and quantum states.
• Resolution boundaries: TEQ’s resolution boundaries are absorbed into ToE’s α‑parameter deformation, allowing entropy curvature to be measured across scales and observational regimes.
• Entropy conservation: ToE extends Noether’s theorem to entropy, showing that conservation laws are entropic invariants and framing gauge and relativistic constraints as entropy‑driven symmetries.
• Integrated entropy families: ToE provides a principled way to embed and compare multiple entropy measures — including Rudolf Clausius entropy, Ludwig Boltzmann entropy, Josiah Willard Gibbs ensembles, Claude Shannon information entropy, John von Neumann quantum entropy, Alfréd Rényi entropy, and Constantino Tsallis non‑extensive entropy — within a unified entropic manifold and α‑deformation scheme, enabling cross‑regime translation, measurement coherence, and limit recoveries.
• Names and personalities in synthesis: ToE explicitly contextualizes and integrates the contributions of major figures — Rudolf Clausius, Ludwig Boltzmann, Josiah Willard Gibbs, Claude Shannon, John von Neumann, Alfréd Rényi, Constantino Tsallis, Guido Fubini, Eduard Study, Ronald A. Fisher, Calyampudi Radhakrishna Rao, Shun’ichi Amari, Nikolai N. Čencov, Tullio Levi-Civita, Bernhard Riemann, Bianconi, Erik Verlinde, Ted Jacobson, T. Padmanabhan, David Sigtermans, and contemporary interlocutors such as Sean Collins — demonstrating how their entropy‑based and geometric models are subsumed within ToE’s entropic field equations and information‑geometric synthesis.

Sean Collins and the Mjolnir (A137) Lattice Dynamics

• Mjolnir (A137) Lattice Dynamics: Sean Collins invented the Mjolnir A137 Lattice Dynamics with lattice path integral formalism, which Obidi has already shown to be derivable from ToE and published online; he has also discussed and engaged with Obidi via private communications.
• Collins–Obidi mapping: ToE identifies a parametric bridge from the ToE Vuli‑Ndlela Integral (entropy‑weighted path integral with irreversibility) to Collins’ lattice path integral via deformation of weighting functionals, effective action terms, and resolution‑controlled boundary conditions, reproducing Collins’ kernels and short‑time propagators as α‑deformed entropic limits.
• Discrete–continuum reconciliation: The ToE framework provides a continuum limit for Collins’ discrete lattice ontology through entropic geodesics and local/spectral action functionals, preserving distinctive lattice features while situating them within ToE’s universal entropic field dynamics.

Additional Achievements and Breakthroughs of ToE

Beyond the classical validations and meta‑theoretical integrations, ToE advances several core breakthroughs:

• Google Quantum Core Observer breakthrough experiment: A proposed observer‑centric framework for quantum experiments that leverages entropic field dynamics to interrogate core states within quantum processors, clarifying the role of entropy gradients in measurement, decoherence, and information flow at scale.
• Vuli‑Ndlela Integral: An entropy‑weighted path integral formalism introducing controlled irreversibility and coarse‑graining, recovering standard quantum limits while enabling entropic deformations and non‑equilibrium dynamics; integrates smoothly with the Obidi Action and the Master Entropic Equation.
• Attosecond entanglement formation time: A predictive entropic timescale for the onset and stabilization of quantum entanglement, mapping formation dynamics to entropy gradients and information‑geometric distances, with attosecond‑level signatures proposed for ultrafast experimental verification.
• Explanation of wave function collapse and the measurement problem: ToE reframes collapse as an entropic selection process driven by resolution boundaries and α‑deformed information geometry, providing a deterministic substrate for probabilistic outcomes via entropy‑weighted dynamics and observer constraints.
• Local and Spectral Obidi Actions: Complementary action formulations — the Local Obidi Action for spacetime‑localized entropic dynamics and the Spectral Obidi Action for frequency‑domain and mode‑resolved entropic evolution — enabling multi‑scale analyses and spectral‑geometric unification within the entropic manifold.
• Entropic Noether framework: A generalization of Noether’s theorem to entropy‑generated symmetries, yielding conservation laws and constraints that recover thermodynamics, gauge conditions, and relativistic invariants as entropic inevitabilities.

Distinguishing Features of Obidi’s Work

Obidi’s research is characterized by:

• Reproducible workflows: Every derivation and proof is documented in a way that can be replicated by other researchers.
• Rigorous LaTeX documentation: Ensuring mathematical precision, professional polish, and archival permanence.
• Open publishing strategies: Designed to maximize scholarly visibility and global outreach, ensuring ToE research is accessible to all.
• Keyword authority and domain visibility: Actively building SEO presence across platforms to position ToE as the definitive source for entropic field dynamics.

Scientific Mission and Vision

Importantly, John Onimisi Obidi’s scientific mission is to establish a lasting, accessible corpus of ToE research that bridges:

• Information geometry — unifying Fisher–Rao and Fubini–Study metrics through Amari–Čencov α‑connections and Levi‑Civita structures within ToE’s entropic manifold.
• Entropy conservation — linking Noether symmetries to entropic invariance principles.
• Spacetime physics — deriving relativity and quantum constraints from entropy dynamics.

This mission is pursued with a commitment to clarity, accessibility, and universality, ensuring ToE remains comprehensible to both technical and non‑technical audiences worldwide.

Expanded Context and Impact

• Meta‑theoretical synthesis: ToE situates and extends other entropy‑based models (e.g., TEQ by David Sigtermans and F-HUB Theory by Waldemar Marek Feldt) within its broader entropic manifold, demonstrating ToE’s superset relationship.
• Philosophical implications: ToE reframes ontology and epistemology in physics, treating entropy as the fundamental “being” from which all phenomena arise.
• Educational outreach: By translating complex mathematical formalism into accessible narrative, Obidi ensures ToE can inspire both scholars and the public.
• Future directions: ToE aims to unify cosmology, quantum mechanics, and information theory under one entropic framework, positioning itself as a candidate for the long‑sought Theory of Everything.

Summary

John Onimisi Obidi’s Theory of Entropicity (ToE) is not only consistent with classical physics but also extends and unifies modern entropy‑based frameworks. Through rigorous documentation, reproducible workflows, and open publishing, Obidi is building a permanent, accessible corpus of research that positions entropy as the fundamental substrate of reality and ToE as a meta‑framework for unifying physics.

Additional Achievements and Breakthroughs of ToE

• Vuli-Ndlela Integral: Entropy‑weighted path integral formalism introducing controlled irreversibility and coarse‑graining.
• Local Obidi Action: Spacetime‑localized entropic dynamics.
• Spectral Obidi Action: Frequency‑domain and mode‑resolved entropic evolution.
• Entropic Noether framework: Generalization of Noether’s theorem to entropy‑generated symmetries.
• Mjolnir A137 Lattice Dynamics: Invented by Sean Collins, shown by Obidi to be derivable from ToE.

ToE Method of Integrating Entropies and Information Geometry

ToE integrates contributions from:

• Ronald A. Fisher and C. R. Rao (Fisher–Rao metric).
• Guido Fubini and Eduard Study (Fubini–Study metric).
• Shun’ichi Amari and Nikolai N. Čencov (Amari–Čencov α‑connection).
• Tullio Levi-Civita (Levi‑Civita connection).
• Bernhard Riemann (Riemannian geometry).
• Classical entropy pioneers: Rudolf Clausius, Ludwig Boltzmann, Josiah Willard Gibbs, Claude Shannon, John von Neumann, Alfréd Rényi, Constantino Tsallis.

This material is sourced from HandWiki Publications: My Publications Homepage: By John Onimisi Obidi (Creator of the Theory of Entropicity (ToE))

References and Supplementary Research Resources

🌐 Explore more: Theory of Entropicity Blog

Further Resources on the Theory of Entropicity (ToE):

1. Website: Theory of Entropicity ToE — https://theoryofentropicity.blogspot.com
2. LinkedIn: Theory of Entropicity ToE — https://www.linkedin.com/company/theory-of-entropicity-toe/about/?viewAsMember=true
3. Substack: Theory of Entropicity (ToE) — John Onimisi Obidi | Substack
4. Medium: Theory of Entropicity (ToE) — John Onimisi Obidi — Medium
5. SciProfiles: Theory of Entropicity (ToE) — John Onimisi Obidi | Author
6. Encyclopedia.pub: Theory of Entropicity (ToE) — John Onimisi Obidi | Author
7. HandWiki contributors, “Biography: John Onimisi Obidi,” HandWiki, https://handwiki.org/wiki/index.php?title=Biography:John_Onimisi_Obidi&oldid=2743427 (accessed October 31, 2025).
8. HandWiki Contributions: Theory of Entropicity (ToE) — John Onimisi Obidi | HandWiki
9. HandWiki Home: Theory of Entropicity (ToE) — John Onimisi Obidi | HandWiki
10. Academia: Theory of Entropicity (ToE) — John Onimisi Obidi | Academia
11. ResearchGate: Theory of Entropicity (ToE) — John Onimisi Obidi | ResearchGate
12. Figshare: Theory of Entropicity (ToE) — John Onimisi Obidi | Figshare
13. Authoria: Theory of Entropicity (ToE) — John Onimisi Obidi | Authorea
14. Social Science Research Network (SSRN): Theory of Entropicity (ToE) — John Onimisi Obidi | SSRN
15. Wikidata contributors, Biography: John Onimisi Obidi “Q136673971,” Wikidata, https://www.wikidata.org/w/index.php?title=Q136673971&oldid=2423782576 (accessed October 31, 2025).
16. Google Scholar: ‪John Onimisi Obidi — ‪Google Scholar
17. Cambridge University Open Engage (CoE): Collected Papers on the Theory of Entropicity (ToE)

Physics

1. Physics:Theory_of_Entropicity
2. Physics:Entropy_Curvature
3. Physics:On the Theory of Entropicity (ToE)

Biography

1. Biography:John Onimisi Obidi

Philosophy

1. Philosophy:Ontology_of_Entropy
2. Philosophy:Entropy_and_Reality

Books

1. Book:On the Theory of Entropicity (ToE)
2. Book:On_the_Theory_of_Entropicity_(ToE)

Wiki General

1. Theory of Entropicity(ToE)