On the Fundamental Principles of the Quantum Theory of Gravity

Abstract This article explores the physical properties of the intermolecular ether, which serves as the primary energy source of gravity and light. In the process of a solid body moving through liquids, its frontal surface compresses the ether within the intermolecular space, generating a gravitational repulsion force. Behind the trailing surface of the body, a cavern is formed—a zone of energetically rarefied ether (a vacuum zone). The sucking-in action of this cavern is known in physics as gravitational attraction. The most rarefied state of the ether within the cavern exhibits properties typically attributed to a "black hole." Under the action of these forces, liquid molecules are swirled into cavitation bubbles. Within these bubbles, the optical properties of the ether change: it loses transparency (forming an "ether fog") and generates a cold glow. This phenomenon renders the physical process of the emergence and propagation of gravity visible: The movement of molecules within the bubble generates a cold glow. However, the bubble itself remains stationary; thus, light is a quasi-motionless substance. A vortex (tornado) forms inside the bubble, generating the force of gravitational attraction. Under this force, the bubbles aggregate into a cluster. The permanent regeneration of bubbles within the cluster ensures the propagation of gravity at a speed of 300,000 km/s. The cluster serves as an analogue of the graviton, which is mistakenly referred to as a “photon”. In the process of generating the gravitational attraction force, the flow of time is altered, providing the theoretical basis for temporal displacement into both the past and the future.