The CoolScientist

By John N. Hait

Antigravity! Doesn’t that sound exciting? For how many centuries have people wanted to understand how to make gravity repel? Probably since people recognized that gravity is the primary reason why people can’t fly like Superman. Even birds do not use antigravity. They move air with their wings, causing aerodynamic forces on the special shape of their bodies and wings to do the job.

In our last CoolScientist lesson we learned how gravity works. The gravitational field induces a slight phase, or timing change in the flowing energy within each atom. This warps each atom in the object immersed in the gravitational field. This warping causes the atom to relocate itself unless there are counter forces to prevent it from moving.

This internal change is highly directional. It is not random, but follows a precise pseudorandom pattern pointing in only one direction, namely in the direction of the mass having the strongest gravity… such as the Earth in our vicinity. Being directional it, therefore, has geometry. If we can change its geometry, then we can change how it works.

The geometry of anything depends on its shape. An aero points in one direction, a golf ball does not. Yet, when you drop the ball, it falls in only one direction… down!

Atoms are affected by gravity, and their nuclei are round. The binding energy that flows on the outside of atoms, hooks them together into all sorts of shapes… all sorts of geometries. The only difference between the bonding energy and that within the atom is its wavelength and its flow pattern…its geometry. One is round and the other is not. Plywood is not round, and neither is the binding energy between its atoms, but the nuclei of each atom in the plywood is spherical.

Einstein said that binding energy is anti-gravitational. Or what some call “negative mass.” That is, in the presence of gravity… it wants to go up rather than down. The catch is that the binding energy is very tiny in comparison to the energy contained in the round nuclei of each atom. So the mass pulling up is small in comparison to the nuclear mass hooked to it, which is pulling down … and so the downward-pulling mass wins.

But what if we could make the nuclei pull up also? Assuming Einstein to be right, then antigravity exists. But what if we could make the nuclear mass pull up too?

The secret lies in examining the magnetic field of a permanent magnet. We can lay a permanent magnet on a table. And if we hold another one just right, we can push the one on the table all over the place without the two magnets touching each other. That is, they repel.

However, the geometry is very tricky. If we move it just off to the side where it pushes, the loose one on the table will suddenly flip around into a geometry that causes the two magnets to attract, and they will suddenly fly together. Thus, the repellant geometry is mechanically unstable, or more precisely, it requires critical alignment. The attractive mode is mechanically stable.

So it is with gravity. The nuclei of all atoms near the Earth have long since swiveled into an attractive geometry, simply because they are round and free to move within the atomic structure. As we move things, the nuclei will also continue to swivel, or gimble, tracking the gravitational field just like a compass will track a magnet as we move the compass around it.

And that is the solution to the age-old riddle of why gravity doesn’t repel…a riddle that has heretofore prevented the unification of all physics into a single easy-to-understand model.

So how does one make antigravity? Simple, just induce an outside field system, which causes the nuclei to flip over into a repellant geometry, and they will suddenly have a strong desire to fly!

You can learn more about resonant fields by reading the easy-to-understand e-book, Resonant Fields: the Fundamental Mechanism of Physics, available at www.coolscience.info on the Internet. (© 2004 by CoolScience)