Physics

The sections that follow do not seek to replace modern physics, but to show that its fundamental structures—constants, spectra, symmetries—can emerge as necessary solutions of a coherent substrate. This work explores how a single geometric principle can give rise, without arbitrary adjustment, to phenomena that recall those of the Standard Model.

In other words, the goal is not to say “what happens” in the world, but to show how the world could describe itself from its most fundamental conditions of existence. Physics retains its experimental, predictive, and quantitative role; what is sought here is the generative structure that makes these forms possible.

This approach may also shed light on certain questions still open in theoretical physics, such as the origin of fundamental constants (for example h, c, G, or the fine-structure constant α), the hierarchy of masses, the nature of gravity, dark matter, or the stability of quantum states at different scales. Within this framework, these phenomena are not arbitrary givens of the world, but structural effects of the way CELA complexifies while preserving internal balance between density and differentiation.

We will focus primarily on the constituents of ordinary matter: quarks, leptons, and interaction-carrying particles (bosons).
But the aim is not to explain physics from CELA; rather, it is to show that physics can necessarily emerge from a process of self-complexification governed solely by the fundamental attributes of the substance of the Real.

Thus, what follows does not describe the world: it shows why the world can be as it is.

Further Reading — Complete Physics Corpus (018–069)

The CdR Physics domain relies on a structured set of images and technical documents forming a coherent path, from fundamental formalism to advanced quantum phenomena.

Fundamental structure (005, 018–022)
- image006 — Physical capacities derived from organizational degrees
- image018 — Visual convention 1D→2D→3D
- image019 — Visual convention 3D→4D
- image020 — Discrete 6D prototype (20 triple-cells)
- image021 — Evolution of a 6D cell
- image022 — Internal 6D geometry
Spacetime (023–029)
- image023 — Θ scale (ℓ*, t*, c, ħ)
- image025 — Dynamic viscosity of the spation
- image027 — Sub-spatial entanglement (6D)
- image028 — Inflareaction
- image029 — Stabilized proto-excitation
Matter (030–042)
- image030 — Transion threshold
- image031 — Combinatorial intersection 6D→7D
- image032 — Visual grammar of transions
- image033 — Entry vortex
- image034 — Double vortex
- image035 — Topological origin of charge
- image036 — Internal modes and spin
- image037 — Dephasing Δφ = π·n
- image038 — Internal static wave
- image039 — Internal origin of mass
- image040 — Φ force fields
- image041 — Structure of the electromagnetic field
- image042 — Complete particle table
Fundamental forces (043–065)
- image043 — CdR gravity
- image044 — Pressure, energy, Φ flux
- image045 — Electrostatic attraction
- image046 — Charge distribution
- image047 — Nucleon structure
- image048 — Internal spationic states (0/3)
- image049 — β⁻ decay
- image050 — Electron capture
- image051 — Θ EM geometry
- image052 — Electrostatics: continuous flow
- image053 — Directional interactions
- image054 — Continuous vs discontinuous regimes
- image055 — Magnetism: transverse effect
- image056 — Interaction between currents
- image057 — Classical EM wave
- image058 — Orbital quantization
- image059 — 2Φ modes and photon
- image060 — CdR photon
- image061 — Refraction / photonic guiding
- image062 — Light–matter interaction
- image063 — Perturbation → wave → photon
- image064 — Coherent range Z_coh
- image065 — Double slit (CdR path)
Entanglement & Non-locality (066–069)
- image066 — CdR structure of long-range entanglement
- image067 — Bell correlations & global Φ coherence
- image068 — Decoherence & multi-photon correlated states
- image069 — Applications (quantum eraser, GHZ, teleportation)

To consult each document in the dedicated editor, use the “Open in viewer” button after opening a file.