1. The Foundation: Energy IS Momentum

Modern physics uses the Stress-Energy Tensor to catalog mass, pressure, and shear stress as distinct sources of gravity. I propose a fundamental physical simplification: All components of this tensor are forms of Momentum Flux.

The Substrate: A Pressurized Superfluid Plenum

This simplification immediately solves one of the most embarrassing failures of the Standard Model: the "Hierarchy Problem" (Why is Gravity 1040 times weaker than the Strong Nuclear Force?).

In CMFT, Gravity is not a weak force acting in a void. It is the Geometric Residual of an immense momentum transfer occurring within a High-Pressure Superfluid Vacuum. Consider a fish in the deepest part of the ocean. It is under crushing pressure, yet it feels weightless. This is because the pressure is Omni-Directional and Equalized.

Matter exists in a similar state. We float in a substrate of immense flux density. Crucially, because the vacuum acts as a Superfluid, it exhibits the property of Zero Viscosity for Bulk Motion. This explains why planets can orbit for billions of years without spiraling into the sun—they are moving below the critical velocity of the medium, effectively "superconducting" through the flux. However, high-frequency excitations (like Light) are shear waves that do interact with the microstructure, leading to energy loss over cosmic distances (see Section 13).

Vacuum Pressure  >>>  Gravitational Residual

Gravity is simply the tiny fraction of this flux that "leaks" (fails to cancel) due to geometric misalignment. We perceive gravity as weak only because we are measuring the Residual Drift (the leak), not the Static Pressure (the reservoir). There is no Hierarchy Problem; there is only the asymmetry of the strongest force in the universe.

The Consequence

Mass is not a static property; it is "trapped" momentum (vortices) within this high-pressure ocean. By treating all matter and energy as vectors of flux, we flatten the universe onto a Euclidean base. Gravity is not the bending of the map; it is the mechanical interaction of these fluxes within the rigid, hyper-pressurized substrate.