Omni-Coherence
Research Group
Reality must remain existent and consistent.
Reality, as a single global physical state, must remain existent, self‑consistent and dynamically stable under all allowed transformations. All physical laws arise as constraints enforcing this global consistency.
ΔS = 0 ⇒ a² = aNa₀ ⇒ v⁴ = G M a₀,
and
a₀ = \(\dfrac{c H₀}{2\pi}\).
Informational Physics Foundations
Zero-Distinction Baseline as the Baseline of Possible Reality
This article introduces the Zero-Distinction Baseline (ZDB) as the baseline of possible reality. ZDB is not a physical state, not a substance, not a process, and not a limit. It is the logical condition that defines when something can appear as a distinguishable manifestation. All physical phenomena—superfluidity, waves, fields, matter, plasma, and spacetime—are understood as differentiations relative to this baseline. A differentiation spectrum is introduced, together with minimal mathematical structure and a vector-style diagram.
Informational Physics Foundations: Zero-Distinction Baseline as the Baseline of Possible Reality. Zenodo.
Open PDF - Informational Physics Foundations
GEC
Global Entropic Consistency Principle (GEC)
Reality is a finite informational whole with a finite horizon and a minimal scale, whose global entropy is constant. Local physical processes are compensating redistributions of information such that ΔStotal = 0.
The Global Entropic Consistency Principle (GEC): A Strictly Physical Axiomatic Framework. Zenodo.
UTHC
Unified Theory of the Horizon Coherence (UTHC): A Conceptual Framework for Infrared Gravitational Physics
UTHC represents the next step in the development of our earlier frameworks CoFiT and GTCF. Both concepts demonstrated that informational and coherence-based principles can explain a wide range of physical phenomena, but they did not pass the tests of universality – they were unable to consistently account for quantum, gravitational, and cosmological phenomena within a single foundational structure.
The Unified Theory of the Horizon Coherence (UTHC) was created as a response to these limitations: it combines their strengths, removes their constraints, and provides a unified informational foundation from which quantum theory, gravity, and cosmology can emerge as manifestations of a single underlying principle.
Unified Theory of the Horizon Coherence (UTHC): A Conceptual Framework for Infrared Gravitational Physics. Zenodo.
Open PDF - UTHC: A Conceptual Framework for Infrared Gravitational Physics (v1)
UTHC
Unified Theory of the Horizon Coherence (UTHC): Mathematics and Observational Tests – Informational Realization
This work is the second part of the Unified Theory of the Horizon Coherence (UTHC) series, extending the conceptual framework introduced in the earlier preprint by developing its mathematical structure and confronting it with observational data. UTHC is an exploratory informational approach in which quantum mechanics, gravity, cosmology, and particle physics emerge from the entropic microstructure of the horizon. Here we derive the informational entropy functional, the flux‑geometry equations, and the infrared RG flow, and we extract the IR exponent ε=0.50±0.02 directly from SPARC RAR data. Through the holographic relation Δ=4+4ε, this yields a data‑driven scaling dimension Δ=6.0±0.08, linking galactic dynamics to horizon microphysics without free parameters. The framework reproduces MOND‑like scaling, flat rotation curves, and the empirical relation a0∼cH0. This preprint should be regarded as exploratory theory rather than established physics.
Unified Theory of Horizon Coherence (UTHC): Mathematics and Observational Tests – Informational Realization (v1). Zenodo.
Open PDF - UTHC: Mathematics and Observational Tests – Informational Realization (v1)
UTHC
Unified Theory of the Horizon Coherence (UTHC): Unity from GEC to Quantum Mechanics, Gravity, and the Standard Model
The Unified Theory of Horizon Coherence (UTHC) proposes that quantum mechanics, gravity, cosmology, and the qualitative structure of the Standard Model all emerge from a single informational substrate governed by the Global Entropic Consistency (GEC) principle.
In UTHC, the horizon is modeled as a discrete network of quantum “pixels” carrying a qutrit Hilbert space. Their entanglement structure defines adjacency, causal order, and the emergent geometry of spacetime. A concrete qutrit-based pixel Hamiltonian is constructed whose ground state:
- reproduces quantum coherence in the ultraviolet (UV),
- yields Einstein gravity in the infrared (IR),
- supports two excitation sectors: flux-like (proto-gauge) and charge-like (proto-fermion), which act as microscopic precursors of gauge and matter fields.
Numerical simulations on toroidal lattices reveal a phase in which the entanglement entropy obeys an area law with a universal subleading correction characterized by an exponent γ = 1/2. This fixes the infrared deviation parameter ε = 1/2 and the scaling dimension Δ = 6 of the leading irrelevant operator deforming the horizon entropy functional.
In this framework, galactic dynamics (including the MOND acceleration scale, the radial acceleration relation, and the baryonic Tully–Fisher relation) arise not from modified gravity or dark matter halos, but as the macroscopic expression of information redistribution in a system with finite horizon capacity. UTHC thus offers a unified informational origin for quantum coherence, emergent gauge and matter sectors, and infrared gravitational behavior.
Unified Theory of Horizon Coherence (UTHC): Unity from GEC to Quantum Mechanics, Gravity, and the Standard Model (1). Zenodo.
Open PDF - UTHC: Unity from GEC to Quantum Mechanics, Gravity, and the Standard Model (1)
Informational Physics
Global Entropic Consistency Principle and the Emergence of Physical Law
Modern physics rests on three ontologically disjoint frameworks—quantum mechanics, general relativity, and the Standard Model—each built on postulated primitives (Hilbert space, metric geometry, gauge fields) that cannot be derived from one another. We resolve this mismatch by introducing a strict two-layer informational ontology.
Layer 0 consists of pure information governed by six Global Entropic Consistency (GEC) axioms. Layer 1 emerges via coarse-graining and renormalization-group flow from an explicit qutrit-pixel Hamiltonian on a toroidal lattice. Spacetime, fields, particles, chiral fermions, and the full gauge group \(U(1)\times SU(2)\times SU(3)\) arise as stable emergent structures rather than fundamental entities.
In the emergent regime we obtain an effective field theory that reproduces the Standard-Model-like sector with hierarchical Yukawa couplings. Numerical MPS/PEPS simulations on \(16\times16\) toroidal lattices confirm the emergence of three fermion generations and a stable Koide relation \(Q=2/3\) for both leptons and quarks.
A central result is the parameter-free derivation of the MOND acceleration scale \(a_0 = cH_0/2\pi\) directly from GEC global entropy conservation and the entanglement structure of the stable UTHC phase (\(\gamma=1/2\)). The same informational substrate predicts modified gravitational dynamics at astrophysical scales, a characteristic weak-lensing slope \(\beta\approx1/2\), and log-spiral modulations in the CMB temperature power spectrum at multipoles \(\ell\approx250{-}450\).
All observable parameters and phenomena are emergent and traceable to the underlying informational dynamics, offering a concrete, falsifiable, and ontologically unified description of fundamental physics.
Informational Physics: Global Entropic Consistency Principle and the Emergence of Physical Law (v2). Zenodo.
Research
We present our further research results in the form of pdf articles and preprints in the Deep Research section. All content published by us is in the Public Domain: All articles are available for unrestricted, anonymous scientific use (non-commercial). They are provided "as is" without warranty. The content is subject to change without prior notice. We kindly request that the terms General Theory of the Coherent Field (GTCF) and Universal Coherence Field Theory (CoFiT) be attributed to the ideas and theoretical framework developed by the Omni-Coherence Research Group.