11. Simulation: Electron-Flux Coherency Test
The simulation results derived in previous sections compel us to re-evaluate the fundamental topology of space. The emergence of a "Core Flux Spike" and the necessity of a "Geometric Inversion" suggests that the standard model of gravity—mass pulling on mass across empty space—is topologically inverted.
We propose a Hydrodynamic Formulation where the vacuum is not "empty," but is a Superfluid Plenum under immense, near-infinite pressure. In this framework, matter is not a "substance" added to the void, but a Soliton (a stable, self-reinforcing void or defect) maintained against the crushing pressure of the vacuum.
11.1 The Inversion Principle
Standard physics views Gravity as Tension (Attraction). The Corley Momentum Flux Theory (CMFT) reinterprets this as Pressure (Displacement).
- Standard View: Fgravity ∝ Mass1 × Mass2 (Pull)
- Inverse View: Fgravity ∝ -∇ Pvacuum (Push)
11.2 The Soliton Mechanism: "Form is Emptiness"
If the vacuum is a high-pressure superfluid, a static bubble would instantly collapse. To exist, matter must actively push back. The Electron Cloud acts as the "Hull" of this bubble. The rapid motion of electrons generates a Momentum Flux—a continuous stream of shockwaves—that holds the vacuum wall at bay.
This simulation tests the mechanical viability of this model by decoupling two critical factors:
- 1. Geometric Opacity (The Shape): In a superfluid, flux streams intersect and create turbulence ("Geometric Tears"). This disrupts the laminarity of the flow, effectively "muffling" the gravitational signal of the deep interior.
- 2. Material Coherency (The Core): To overcome this muffling and produce the gravity we actually observe (9.81 m/s²), the Earth's core must force the Iron lattice into a "Super-Conductive" state, generating a Core Flux Spike.
Analysis: The Feasible Range of Reality
The simulation results (Stage 2) reveal a fascinating non-linear relationship. While Newtonian physics assumes a static constant (G), the Hydrodynamic model suggests that Flux Efficiency is dynamic. The scan in Stage 1 reveals that a spherical arrangement of matter defines a specific Geometric Efficiency curve.
This characteristic quadratic fall-off is a function of the Network Intensity—the mapping of all interacting particle pairs within the volume. While the internal flux density acts to suppress soliton stability, the interaction creates a resistance that geometrically squares the connection to the Sagitta Drift. Consequently, the core becomes a focused generator of high-tension flux due to this geometric pressure, while the surrounding mantle appears to act as a relative dampener.
Experimental Evidence: The Earth's Core Anomaly
Our "Inverse Flux Scanner" reveals a critical discrepancy when applying this model to Earth. As shown in the table below, the Earth's interior is Gravitationally Opaque (Geff < 1.0) due to these geometric interactions.
| Region | Geometric Efficiency (Geff) | Observed Gravity (g) | Required Flux Output |
|---|---|---|---|
| Surface (6371 km) | 0.965 (Transparent) | 9.81 m/s² | 10.16 m/s² |
| Core Boundary (3400 km) | 0.882 (Muffled) | 10.43 m/s² | ~12.80 m/s² |
To reconcile this geometric reality with observed gravity, the "Auto-Solve" function dynamically determines the required Coherency Factor (ηFe).
Rather than relying on a fixed constant, the simulation demonstrates that a precise fit exists where the material coherency aligns with the geometric pressure curve. The tool allows us to tune the model to find the specific range where the calculated flux output matches the PREM reference data. This confirms that the immense pressure at the core forces the Iron lattice into a coherent state, acting as a "Gravitational Super-Conductor" that overcomes the geometric muffling to produce the gravity we observe.