Mechanisms

Mechanistic Foundations of Charge Admittance

Background

The Charge Admittance (CA) theory originated from a mathematical framework in the early 2000s to predict electromagnetic (EM) antenna field patterns. It models energy not as abstract quanta alone but as resonant flux dipoles, describing photon energy as waves — EMlets — that propagate through a structured impedance field.

Origination of Motion: Wave Creation

There are two types of EM wave creation:

  • Single-ended (unidirectional motion through asymmetric field tilt)
  • Bi-directional (paired motion from symmetric energy collapse)

This process explains the emergence of localized energy motion before full particle formation.

Spin

In classical quantum mechanics, spin is an intrinsic, quantized property of particles. In CA, spin emerges from the aberrant motion of charges seeking energetic equilibrium. It is not literal angular rotation, but a topological consequence of dynamic imbalance in resonant charge dipoles.

Spin ∝ Field Aberration in Charge Equilibration

CA interprets spin as arising naturally from the vector coupling of sub-photonic motion under dynamic impedance constraints. Integer and half-integer values reflect stable periodic coupling.

First Lattice (Primordial Medium)

To address Einstein’s concern about how space can propagate energy, CA proposes a primordial lattice: a structured field defined by vacuum permittivity (ε0) and permeability (μ0). This lattice is the energetic substrate that permits propagation via impedance.

Lattice Medium = f(ε₀, μ₀)
A transmission line of space, not substance.

First Tilt (Gravitational Genesis)

Gravity in CA is not a mutual attraction but a gradient alignment of local impedance fields. When two field structures exist, their orientations induce a tilt in the lattice, guiding energy flow.

Gravitational Tilt ∝ ∇(Field Alignment)
Force ∝ ∇(Impedance)

This “first tilt” induces motion not through pulling, but via a slope along the impedance structure of space.

First gravity

The novel perspective that gravity is intricately linked to energy introduces a fresh viewpoint on its origin. The narrative unfolds with the inception of a charge Jerk wave coming into a confluence with another. This connection isn’t rooted in a mutual repulsion or attraction between the two charges but their combined fields interacting to change the Z0 field gradient.

g ∝ ∇Z₀ from wave interference.

Rest Energy and Impedance Coupling

At the heart of CA is the idea that rest energy couples with space’s impedance to produce observed acceleration and force effects.

Rest Energy (E₀) ∝ Z₀ Coupling

This explains how localized fields (like particles) interact with far-field impedance and produce force-like effects — including gravity, strong, weak, and EM forces — through impedance matching.

Energy Concentration

Lorentz forces govern energy concentration via the inverse-square law. These concentrated regions form gradients in ε₀ and μ₀, sculpting the lattice.

Field Strength ∝ 1/r²
∇(ε₀, μ₀) ∝ Energy Concentration

Gravity then emerges from the flow of energy down these gradients.

Resonance and Oscillation

Resonance occurs when energy systems align in frequency and phase:

Resonance ⇔ Phase Synchronization

This is essential for:

  • Photon-photon coherence
  • Charge vector alignment
  • Collective field formation

In-Resonance State: {E_photons, f, ϕ} matched across 4D

This is how CA explains wave propagation, antenna coupling, and energy scaling.

Self Resonance

Self-resonance is the feedback loop where systems oscillate at their natural frequency without external input. This explains behaviors from molecular vibration to radioactivity.

Self-Resonance → Internal Amplification → Energy Leakage

In CA, radioactive decay may result from unstable self-resonant states within a charge lattice.

Filtering

Multi-frequency filtering arises from near-wavelength attractions within the Z0 field. Similar but distinct frequencies group into harmonics or sidebands.

Filtering ∝ Group Resonance(f₁ ≈ f₂ ± δf)

This mechanism aligns sub-harmonic photon groups for stable energy structures and drives coherent behaviors in the universe.

Wave Formation

Waves in CA are coherent ensembles of photons, not sinusoidal abstractions. The amplitude slope of the wave reflects the net energy, while individual photons carry localized energy states.

E_wave ∝ Slope(Amplitude) × Cohesion(Photons)

An EM wave is analogous to a water wave: many H2O molecules form the amplitude, but energy is within the molecules.

Wave Energy = ∑ E_photon(∂ϕ/∂x)

Energy Propagation

CA models energy propagation like a transmission line. Energy flows toward the lowest impedance:

dE/dt ∝ -∇Z (Energy seeks impedance minima)
Far-field Flow ⇔ No Return Path

This underlies black hole feeding, EM radiation, and long-distance transfer.

Equilibrium and Entropy

Energy flow is governed by equilibration across impedance gradients, with entropy representing the system’s state change.

Entropy ∝ Rate of Equilibration Across ∇Z

Changes in energy field parameters (e.g., frequency, amplitude) propagate throughout the lattice.

Redshift

CA attributes redshift to cumulative impedance transformations, rather than just motion or mass-related gravitational time dilation.

Δλ ∝ ∫ ∇(ε₀, μ₀) over photon path
Low-f Redshift ≈ Exponential Falloff

This model anticipates greater redshift at lower frequencies, consistent with expansion and entropy increase.

Deflection

Energy path bending — gravitational lensing, scattering, sideband mixing — results from field fluctuations in ε0 and ​μ0:

Deflection ∝ ∇Z × Path Curvature
Gravitational Lensing ⇔ Spectral Mixing

Mixing can generate both frequency offsets and novel particles (nonlinear combinations).

Wave Recovery and Transduction

To extract work from an EM field:

  1. A current path must be established — usually via impedance shift (e.g., dipole excitation)
  2. Field strength must be captured via phase-matched resonance

I = dQ/dt, from E_dipole via Near Field → Far Field → Recovery

Examples:

  • Antennas: couple EM field into current
  • Zero-impedance detectors: convert charge directly
  • Transformers: use magnetic flux to induce current

Particle formation

Particles emerge from stable energy toroids, where magnetic fields are fully enclosed and cannot radiate outward.

Stable Particle ⇔ Closed B-field + Arcing Dipole Collapse

Toroidal structures below vacuum breakdown voltage prevent current collapse and store energy locally — enabling persistent, particle-like behavior.