Antigravity experiment to go to Mars

[Valeriy Tarasov]

The Gravity mechanism​

In h‑space theory ( https://hspacetheory.wordpress.com ) gravity isn’t viewed as a curvature of spacetime (as in general relativity) but instead as a consequence of a density gradient in the very “vacuum” particles that make up space. These vacuum particles are the n=0‑objects(I) that, in this theory, constitute the fundamental “stuff” of space itself. When a massive body is present, it displaces some of these n=0‑objects(I), causing their density (denoted ρ₀) to drop around the body. This reduction creates a gradient in the density of vacuum particles, and other bodies “fall” along this gradient toward the mass. The gravitational force is modeled by summing contributions from these displaced particles over a spherical surface (using a 1/4πR² factor). In other words, the gravitational attraction between bodies arises from the difference in the local density of n=0‑objects(I) rather than from the bending of a spacetime fabric.

This mechanism even predicts phenomena such as gravitational redshift (since a lower ρ₀ near a mass causes shifts in the wavelengths of emitted light) and provides an explanation for black holes, where the density drop is so severe that the attraction speed exceeds the speed of light, trapping light within the body .

While conventional theories attribute gravity to geometric deformations of spacetime, h‑space theory attributes it to the microscopic rearrangement and displacement of discrete vacuum particles. This interpretation leads to a gravitational interaction with a maximum effective range (or boundary) that depends on the mass of the body—a feature that the theory uses to address issues such as galaxy rotation curves without invoking dark matter.

Antigravity experiment​

General description
In h‑space theory the antigravity experiment is designed to test the prediction that a controlled local increase of density ( ρ₀) of the vacuum’s particles can produce a measurable repulsive force against gravity.

Technical scheme​

To achieve the local increase of density ( ρ₀) of the vacuum’s particles the pulsing current at Gigahertz frequency is needed and it will produce increase of local density resulting in antigravity. The speed of relative movement of the vacuum particles (which is slightly more than the speed of light in h-space theory) defines the gigahertz range. At lower frequencies the density of the vacuum’s particles will decrease faster than it will be generated by pulsing electrons.

I propose to perform the lab bench experiment where the magnetron, operating at Gigahertz frequency range, is used with the antenna of asymmetrical hollow disk . The disk is connected in its middle to output of magnetron and magnetron is connected to the ceiling through the spring balance. Two forms of disks should be tested: one has more spherical surface at the top and the second one has more spherical surface at the bottom. The expected loss of weight should be detected by spring balance at certain frequencies of magnetron for one of the disk shapes.