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Tuesday, 12 May 2026

Theory of Entropicity (ToE) — Consolidated Archive of Published Papers, Letters, Notes, and Early Publications, the Inaugural Papers (Feb. 2025–Apr. 2026)

Theory of Entropicity (ToE) — Consolidated Archive of Published Papers, Letters, Notes, and Early Publications, the Inaugural Papers (Feb. 2025–Apr. 2026) 

Description / Abstract

This record contains the complete consolidated archive of the Theory of Entropicity (ToE) as published across multiple platforms between Feb. 2025 and Apr. 2026, including all PDFs previously hosted on Figshare. The ZIP file preserves the original versions, publication order, and scientific continuity of the early ToE corpus.

The Theory of Entropicity is a developing framework in theoretical physics that places entropy as the ontological primitive of physical reality. Across the Letters and supporting documents, the ToE introduces:

  • the Obidi Action, a variational principle grounded in entropic dynamics

  • the κ–ρₛ entropic field pair, describing the geometry of entropic flow

  • the Entropic Seesaw Model, explaining emergent stability and asymmetry

  • the Least Entropic Resistance Principle, governing natural evolution

  • derivations connecting entropy to electromagnetism, c, mass, and field propagation

This archive includes:

  • All ToE Letters (PDF) — including foundational Letters I, IIA, IIB, and subsequent expansions

  • Supplementary notes and early conceptual drafts

  • Figures, diagrams, and mathematical derivations embedded within the PDFs

  • Historical versions preserved exactly as originally published

  • A complete ZIP package for long‑term preservation and citation

The purpose of this Zenodo record is to provide a stable, citable, DOI‑backed home for the early development of the Theory of Entropicity, ensuring that researchers, collaborators, and future readers can access the full historical trajectory of the theory in one place.

This consolidated archive complements the ongoing Living Review Letters Series, which continues to evolve through updated derivations, expanded commentary, and refined mathematical structure.

 

Keywords 

entropy; entropic field; Obidi Action; κ field; ρₛ density; entropic dynamics; theoretical physics; speed of light; emergent constants; ToE; Theory of Entropicity; entropic geometry; field equations; entropic propagation

 

Notes for Readers

  • The ZIP file preserves the original folder structure and file names exactly as they appeared on Figshare.

  • PDFs are fully readable online; ZIP contents can be downloaded for archival study.

  • Later, updated versions of the Letters may appear in separate Zenodo records as part of the Living Review series.

 

Suggested Citation

Obidi, John Onimisi (2026). Theory of Entropicity (ToE) — Consolidated Archive of Published Papers, Letters, Notes, and Early Publications (Feb. 2025–Apr. 2026). Zenodo. DOI: 10.5281/zenodo.20151260

 

Technical Description with Equations Included

This consolidated archive contains the foundational manuscripts of the Theory of Entropicity (ToE), preserving the original PDFs and supporting documents from the 2019–2026 development period. The Letters formalize entropy as the ontological primitive of physical law and introduce the Obidi Action, a variational functional defined on entropic configurations rather than geometric or field‑theoretic primitives.

At the core of the ToE is the Obidi Action:

SObidi=∫κ(x) ρs(x) d4x

where:

  • κ(x) is the entropic curvature field

  • ρₛ(x) is the entropic source density

This pair forms the fundamental entropic conjugate fields of the theory.

From this action, the Euler–Lagrange variation yields the entropic field equations:

∂κ∂t=−∇⋅(ρsv)
∂ρs∂t=−∇⋅(κu)

These equations describe the bidirectional entropic flow that underlies all physical propagation.

A central result of the Letters is the emergence of the speed of light c as an entropic transport constant, not a geometric invariant. In the ToE framework:

c2=κρs

This relation shows that c arises from the ratio of entropic curvature to entropic density, giving it a natural origin within the entropic substrate.

The Letters also derive Maxwell‑type propagation from entropic gradients. Defining the entropic potentials:

Es=−∇κ,Bs=∇×As

the ToE yields wave equations of the form:

∇^2κ−(1/c^2)(∂^2κ/∂t^2)=0

demonstrating that electromagnetic‑like propagation is a secondary phenomenon emerging from entropic dynamics.

The archive preserves:

  • the original mathematical structure

  • historical ordering

  • conceptual progression

  • early derivations of the Entropic Seesaw, Least Entropic Resistance Principle, and entropic curvature asymmetry

This record serves as a reference point for ongoing ToE development and for researchers examining entropic formulations of physical law.


The archive also documents the development of several key conceptual structures:

  • the Entropic Seesaw, describing asymmetric entropic curvature and stability regimes

  • the Least Entropic Resistance Principle, governing natural dynamical evolution

  • the entropic interpretation of mass, inertia, and field propagation

  • the entropic origin of symmetry breaking

  • the Riemann–Obidi trajectory, describing entropic geodesics

Together, these components form the early scaffolding of a theory that seeks to unify physical behavior under a single entropic ontology.

This archive preserves the original versions, historical ordering, and mathematical progression of the ToE manuscripts. It provides a stable, citable foundation for ongoing development and for researchers exploring entropic formulations of physical law. The materials contained here represent the first complete consolidation of the early ToE corpus and serve as a reference point for the Living Review Letters that continue to refine and expand the theory.

How Has Obidi Explained the Origin of the Speed of Light c Using His Theory of Entropicity (ToE)?

How Has Obidi Explained the Origin of the Speed of Light c Using His Theory of Entropicity (ToE)?

 

John Onimisi Obidi explains the origin of the speed of light ($c$) through his Theory of Entropicity (ToE), which reinterprets it as an emergent entropic limit rather than a fundamental geometric constant. [1, 2]
According to Obidi:
  • The Entropic Field: There is a universal entropic field that acts as the fabric of reality, from which space, time, and matter emerge.
  • Maximum Rearrangement Rate: The speed $c$ represents the maximum rate at which the entropic field can redistribute or rearrange entropy.
  • Light as a "Tracer": Light travels at this speed because it is massless and exists "at the edge" of interaction, meaning it simply moves at the fastest possible speed allowed by the field's transmission of change.
  • Origin of Invariance: Because all observers and instruments are themselves made of this same entropic field, they all measure the same maximum limit ($c$), regardless of their motion.
  • Mathematical Convergence: Obidi argues that Maxwell’s electromagnetic derivation of $c$ ($c = 1/\sqrt{\epsilon_0\mu_0}$) is simply the "physical language" for what is fundamentally an entropic value, denoted in his theory as $c_e = \sqrt{X/C}$. [1, 3, 4, 5, 6]
In short, Obidi posits that we measure the speed of light because we are seeing the maximum entropic rearrangement rate of the universe in action. [1]

Would you like to explore the specific Master Entropic Equation (MEE) Obidi uses to link these constants?

 

 

 

John Onimisi Obidi explains the origin of the speed of light (\(c\)) through his Theory of Entropicity (ToE), developed between 2025 and 2026, which reinterprets \(c\) not as a fundamental geometric constant of spacetime (as in Einstein’s relativity), but as an emergent entropic limit. [1]
According to Obidi, the speed of light is the maximum rate at which the "Entropic Field" — the underlying, updating fabric of reality — can rearrange or redistribute information (entropy). [1, 2]
Here is how Obidi explains the origin and constancy of \(c\):
  • Entropy as the Substrate: ToE argues that gravity, time, and space are emergent properties of entropy gradients. The entropic field has a maximum reconfiguration tempo, or "heartbeat," that dictates the speed of all interaction, including light.
  • Light as a "Tracer": Light is not merely a wave traveling through space, but a massless entity that travels at the boundary of this entropic rearrangement. It serves as a visual tracer for the maximum entropic interaction rate.
  • The "No-Rush" Theorem: Obidi introduces the "No-Rush" Theorem (Nature Cannot be Rushed), which posits that the universe imposes a non-zero time limit on the reconfiguration of entropy. This limit is what we measure as \(c\).
  • Constant Rate of Updating: The speed of light is constant because it is a property of the field’s internal architecture. Because observers and instruments are part of this entropic field, they cannot measure a speed faster than the field’s own update rate. [1, 2, 3, 4, 5]
Core Mechanism in ToE:
Obidi formulated the Master Entropic Equation (MEE) and proposed that \(c\) is determined by entropic stiffness (\(X\)) and entropic capacity (\(C\)), formulated as \(c_e = \sqrt{\frac{X}{C}}\). This means that if the underlying entropic field in a region differs, the "invariant speed" could theoretically vary, offering a new perspective on cosmic expansion. [1, 3]

 

If you'd like to explore this further, we can help you understand:
  • The difference between standard electromagnetism (Maxwell) and Obidi's Entropic Field
  • What "Entropic Resistance" means for time dilation
  • The implications of superluminal expansion in this theory
Let us know what interests you most!

The Entropic Origin of the Speed of Light c

The Entropic Origin of the Speed of Light c



The Entropic Origin of the Speed of Light







Abstract


This letter — Letter C in the Letter IIA extract of the Theory of Entropicity (ToE) Living Review Letters Series — provides the complete, rigorous, fully formal derivation of the universal speed of light c from the Obidi Action and the Obidi Field Equations (OFE). The central result is the No-Rush Theorem (Theorem C.2), which establishes that c is the maximum rate of entropic rearrangement on the entropic manifold — a finite, universal, and dynamically determined quantity, not a postulate, and not a tautologically defined constant. The derivation proceeds in six logical steps: (i) the quadratic entropic Lagrangian is established uniquely from five symmetry and consistency constraints; (ii) the Euler-Lagrange equations yield the entropic wave equation; (iii) the wave speed cent = √(κ/ρS) is identified as a pure ratio of response coefficients; (iv) dimensional analysis and Planck-scale matching derive κ and ρS independently from first principles; (v) the self-consistency equation is shown to be non-trivial by virtue of the No-Rush Theorem; and (vi) cent is identified with the empirically measured universal speed limit. The Letter responds comprehensively to all known forms of the Tautology Objection, demonstrates the precise structural analogy with Maxwell's 1865 derivation, and articulates the novel predictions that distinguish the ToE derivation from both Maxwell's approach and Einstein's postulate. The Maxwell-Obidi Reframing — that electromagnetic waves are entropic phase waves, and the speed of light is the entropic speed limit — is established as a deep theorem rather than a verbal metaphor.
This Letter reveals that ToE’s entropic stiffness κ and entropic inertia ρ_(S )are not arbitrary constructs but are tightly unified with the Bekenstein–Hawking–Unruh (BHU) thermodynamic framework, marking a profound conceptual convergence between entropic field dynamics and black hole thermodynamics. 
This shows that ToE’s entropic stiffness κ and entropic inertia ρ_S  emerge from the same underlying entropic structure that gives rise to the Bekenstein–Hawking–Unruh relations, thus establishing a deep equivalence between entropic field dynamics and black hole thermodynamics.


Preamble: The Bedrock Question


This preamble establishes the intellectual context for the entire Letter. It formulates the Tautology Objection with precision, provides an initial intuitive response, and maps the route by which the full response will be constructed across the ten sections that follow.

P.1 The Question That Animates This Letter


There is a question that sits at the heart of the Theory of Entropicity — a question that, if left unanswered, would undermine the entire program of deriving the fundamental constants of physics from a deeper entropic substrate. The question is this: does the Theory of Entropicity (ToE) genuinely derive the speed of light c from first principles, or does it merely define c circularly and dress the circularity in the language of derivation?
This is not a peripheral or merely technical question. It is the bedrock question — the question upon which the scientific legitimacy of the ToE's treatment of electromagnetism ultimately rests. If the derivation of c from the Obidi Action is a tautology, then the celebrated expression
(C.0) c = √(κ / ρS)
carries no explanatory force whatsoever. It would be no more informative than the equation c = c — an algebraic triviality masquerading as a theorem. And if that is so, then the entire Letter IIA program— the derivation of Maxwell's equations, the identification of the electromagnetic field as the phase sector of the entropic field, the re-interpretation of all of physics in entropic terms — would risk resting on a vacuous foundation. 

Our task here, therefore, is to show that this is not the case: that the appearance of cin κand ρ_Sreflects dimensional bookkeeping rather than hidden assumption, and that the ratio κ/ρ_Sacquires its physical meaning only through the LOA dynamics and the self consistency theorem.

This Letter provides the complete, rigorous, and conclusive answer to that question. The answer is: emphatically, definitively, and provably NO — the derivation is not a tautology. But the argument that establishes this answer is subtle, multi-layered, and requires careful attention to the logical order of the derivation, the physical meaning of the coefficients involved, the role of dimensional analysis and Planck-scale matching, and the content of the No-Rush Theorem. Rushing to the conclusion — as critics of the ToE sometimes do — produces the apparent tautology; attending carefully to the full derivation dissolves it.

It is worth emphasizing from the outset that this is not a defensive Letter. The Theory of Entropicity does not need to apologize for the appearance of c inside the definitions of κ and ρS. Rather, this Letter demonstrates that the very appearance that looks circular is in fact the signature of a deep self-consistency — a self-consistency that is proved by the No-Rush Theorem and confirmed by the empirical identification of cent with the measured universal speed limit. The apparent circularity, when understood correctly, is evidence of the theory's coherence, not its vacuity.

P.2 The Apparent Circularity: Stated Precisely

Let us state the Tautology Objection with complete precision, in its strongest form, so that the refutation cannot be accused of attacking a weakened version. The objection runs as follows.
The ToE asserts that the speed of entropic propagation is:
cent = √(κ / ρS)
where κ is called the entropic stiffness and ρS is called the entropic inertia. Examining the explicit expressions for these quantities:
κ = kB c3 / G
ρS = kB c / G
where kB is the Boltzmann constant, G is Newton's gravitational constant, and c is — the critic immediately notices — the very speed of light whose derivation is supposedly being accomplished. Substituting these expressions into the formula for cent:
cent = √(κ / ρS) = √((kB c3 / G) / (kB c / G)) = √(c3 / c) = √(c2) = c
The equation cent = c follows algebraically, but trivially — the c has simply cancelled with itself, leaving a tautology. The objection concludes: if κ and ρS are defined in terms of c, then the equation cent = √(κ/ρS) is not a derivation of c but a circular re-statement of the value c was given at the outset.

The "derivation" derives nothing.

This is the sharpest and most powerful form of the objection. It is not based on a misreading; the algebraic substitution is correct. The question is whether the algebraic substitution correctly represents the logical structure of the ToE derivation — and the answer to that question is: it does not.
P.3 The Answer: A Roadmap
The refutation of the Tautology Objection operates at six distinct levels, corresponding to the six logical steps of the derivation. Each level removes one layer of the apparent circularity and reveals the genuine content beneath it.

Level I — The Lagrangian is not assumed, it is derived. The Lagrangian of the entropic field, Lent = (ρS/2)(∂tS)2 − (κ/2)(∇S)2, is not an assumption of the theory. It is the unique Lagrangian consistent with five symmetry and consistency requirements: locality, isotropy, time-reversal symmetry, quadratic truncation (for the linearized theory), and the absence of an explicit potential (for the free-field sector). Section 2 establishes this uniqueness in detail. The coefficients κ and ρS appear as unknown positive real numbers at this stage — they are given no numerical values whatsoever.

Level II — The wave equation is derived without assuming c. Applying the Euler-Lagrange equations to Lent yields the entropic wave equation. From this equation, the propagation speed cent = √(κ/ρS) is identified as a pure ratio of the two response coefficients. At this stage, cent has no assumed value — it is a positive real number whose value is entirely determined by the (still unknown) ratio κ/ρS. Section 3 provides the complete derivation.

Level III — κ and ρS are determined by the Planck-scale physics. The numerical values of κ and ρS are not free parameters — they are constrained by the fundamental physics of the entropic-gravitational regime. Dimensional analysis establishes that the only dimensionally consistent combinations of the fundamental constants kB, G, and the (as-yet-undetermined) cent that give the correct dimensions for entropic stiffness and inertia are κ ∼ kB cent3/G and ρS ∼ kB cent/G. This is confirmed independently by black hole thermodynamics (Section 4).

Level IV — The self-consistency equation is non-trivial. Substituting the Planck-scale expressions for κ and ρS into cent = √(κ/ρS) gives cent = √(α/β) cent, where α and β are numerical coefficients determined by the dimensional analysis. This self-consistency equation reduces to the constraint α = β — a non-trivial prediction about the relative magnitudes of the stiffness and inertia coefficients that must be verified independently. It is not trivially satisfied (Section 4.5).

Level V — The No-Rush Theorem fixes cent uniquely. The No-Rush Theorem proves that cent is finite, universal (the same for all entropic processes), and unique. These three properties, combined with the empirical observation that all massless physical processes travel at the same speed c = 2.997924 × 108 m/s, uniquely identify cent = c. This is an empirical constraint applied to a theoretical prediction — the standard procedure of physics, not circular reasoning (Section 5).

Level VI — The derivation makes novel predictions. A tautology, by definition, makes no predictions. The ToE derivation of c makes at least four novel, empirically testable predictions beyond Maxwell and beyond GR. The existence of these predictions is decisive proof that the derivation is not a tautology (Section 6).

P.4 The Maxwell-Obidi Reframing (TMOR)

Running through all ten sections of this Letter is a central conceptual claim — the Maxwell-Obidi Reframing — which asserts that the electromagnetic field is one emergent sector of the fundamental entropic field, and that the speed of light is not a property of electromagnetism but a property of the entropic manifold itself. This reframing transforms Maxwell's celebrated conclusion into a special case of a deeper entropic theorem.

Maxwell's original statement (1865) was:
"We have strong reason to conclude that light itself — including radiant heat and other radiations, if any — is an electromagnetic disturbance in the form of waves propagated through the electromagnetic field according to electromagnetic laws."

The ToE Reframing (Obidi, 2026) extends and deepens this conclusion:

"We have strong reason to conclude that light itself — including radiant heat and other radiations, if any — is an electromagnetic disturbance which is ultimately an entropic disturbance in the form of waves propagated through the electromagnetic field component of the entropic field which ultimately evolves according to electromagnetic laws arising from entropic laws integral with the entropic field."
This reframing is not merely verbal. It constitutes a genuine explanatory advance: whereas Maxwell explained the properties of light in terms of the electromagnetic vacuum, the ToE explains the properties of the electromagnetic vacuum in terms of the entropic vacuum. The speed of light is not a property of the electromagnetic field; it is a property of the entropic field. The electromagnetic field inherits c from the entropic field because it is a sector of the entropic field.

Understanding this reframing in its full depth requires the complete derivation that this Letter provides. We now proceed to that derivation, beginning with the history of c — a history that reveals, at each stage, a deepening ontological understanding of what c actually is.