The Source Field Investigations (42 page)

Now we’re onto something. If we can push the whirling movement inside an atom past the speed of light, then we’ve just popped that atom over into time-space. It wasn’t until very recently that I realized there was an even more important concept hiding behind this: The motion inside the atom is already going at the speed of light, or very close to it—so it doesn’t take much to finish the job. Right then, years and years of weird little scientific facts I had been collecting in my mind all came together—and I had one of the finest Eureka moments of my entire life.

Physical matter is always right on the edge between these two realities. All we need to do is give it a little push to get it over the boundary—and flip it into time-space. This is how our buckyballs were able to turn into a wave just by slamming against a wall. Protons, neutrons, electrons and atoms in the quantum realm are flip-flopping all the time. You can’t necessarily see the atoms disappear out of a solid object when they flip into waves, but once I realized this is what they were doing, it became clear that others had observed and measured it happening.

For example, Dr. Nikolai Kozyrev found that simply smashing an object against a hard surface would cause its weight to decrease. In one case, he smashed a ball bearing against a lead plate, and weighed it before and after the collision. In another case, he dropped a piece of lead against a stone basement floor. Some of the atoms popped over into time-space just from being bumped—and the objects weighed less. Even better, “These experiments showed that the weight defect does not disappear immediately after a collision, but decreases gradually—with relaxation times of about 15-20 minutes.”
²¹
That means that the missing weight slowly comes back as those atoms quiet back down. They don’t immediately return to light or sub-light speeds—there is a fifteen to twenty-minute delay involved. This again suggests we are dealing with a fluidlike flow between our two “parallel realities” of space-time and time-space.

Smashing the objects with violence wasn’t necessary either. In another experiment, Kozyrev found that simply shaking a weight up and down thirty times by hand was enough to cause its weight to go down.
²²
The strangest part of all was that the weight did not all come back in a nice, smooth curve—it came back in sudden little quantized jumps over time. Each time the weight suddenly changed, its newest increase in mass was proportional to the others. Each weight change was also proportional to the total amount of mass that disappeared in the first place.

If this is confusing, the easiest way I can explain it is by using a hypothetical example. If you smash a weight and it loses a hundred milligrams, let’s say, it might initially gain back ten milligrams. Then you wait . . . but nothing happens. Then, suddenly, it gets ten milligrams heavier. Then nothing happens for a while. Then ten more milligrams appear. This keeps on happening over the course of fifteen to twenty minutes. According to Kozyrev, “We succeeded in obtaining fivefold and even tenfold effects.” He also found out that this so-called effect quantization actually “takes place in almost all the experiments.”
²³
So again, we are looking at a basic property of physical matter. As the atoms pop back in from time-space, they don’t do so in a nice, smooth, even fashion—it’s as if there were layers within each atom. Each layer only pops in once it has slowed back down enough to cross over the light-speed boundary. That means individual atoms could be both in and out of our reality at the same time, depending on which layer you’re looking at. This will make much more sense once we discuss the layers of geometry you will find within each atom—but that comes later.

So again, the basic idea is that by smashing, bumping or even just shaking an object, some of its atoms pop over into time-space and its weight goes down. This also explains Dr. Bruce DePalma’s mysterious Spinning Ball Experiment. DePalma was working for Polaroid in photographic sciences, and lectured part time at MIT. One of his students wanted to see if there was a difference between the effect of gravity on a rotating object and a nonrotating object. DePalma designed an experiment to help find the answer. Two one-inch-wide ball bearings were given a “precisely measured thrust” that should normally cause them to rise and fall in exactly the same arc. The only difference between the two was that DePalma used a hand router to get one of them spinning at 18,000 revolutions per minute, or 300 revolutions per second, first—so this is obviously a very fast spin. He then launched them off in the dark, and photographed the results with a sixty-cycle strobe light. The results were explained on the official Bruce DePalma Web site.

Since the spinning ball traveled higher, that obviously meant it had become lighter. And since it plunged faster than ordinary gravity should allow, that also suggested it was then moving slightly faster in time as well. DePalma didn’t know exactly what was causing the ball to fly higher—but once I figured it out, many other pieces fit together. Nairz saw the same thing when he slammed a buckyball against the wall, and Kozyrev saw it by smashing ball bearings and vigorously shaking weights. Then when we add in Ginzburg, we now have a theoretical framework: as soon as a particle begins to move, part of it will transform into pure Field.

DePalma found that you didn’t even need to shoot the balls through the air—simply dropping two ball bearings straight down, from a height of only six feet, “repeatedly demonstrated a small but significant and clearly perceptible effect” if one of them was rotating at a fast speed.
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DePalma got his results published in the
British Scientific Research Association Journal
in 1976. He also explained it to Dr. Edward Purcell, one of Harvard’s top experimental physicists. Dr. Purcell definitely realized what the implications of this really were: “According to DePalma, Purcell, after contemplating the experiment for several minutes, remarked, ‘This will change everything.’”
²⁶
In his 1977 paper on the Spinning Ball Experiment, DePalma revealed he had the same basic idea as Kozyrev.

“Time as a manifestation of a much deeper and basic force is what we have a concern for here. The point of connection I want to make is the inertia of objects relates to the time energy flowing through them.”
²⁷
Sounds familiar.

So far, all we’ve done is create a small effect that you need special laboratory equipment to even notice. That’s not very exciting. How do we get the really good stuff to happen on a larger scale? In order to find the answer, we have to go back and take another look at gravity. Remember that in Larson’s model, gravity is all there is. Atoms and molecules are nothing more than vortexes within an energy field we call gravity.

CHAPTER FOURTEEN

P
rotons, neutrons, electrons, whole atoms and even clusters of sixty or more atoms called buckyballs have all been found to pop in and out of a wavelike state, where they no longer appear to exist. With the help of Larson’s new physics model, we now see that these particles are popping into a parallel reality called time-space, where time is three-dimensional. Dr. Vladimir Ginzburg turned a classic Einstein equation upside down and found that atoms and molecules lose mass as they are accelerated to the speed of light and beyond. Then we discovered that by simply smashing or shaking an object, as in Kozyrev’s experiments, or rapidly rotating an object, as in DePalma’s Spinning Ball Experiment, we can apparently accelerate the internal movement in an atom past light speed—and measurably reduce its weight. Kozyrev also found that it took about fifteen to twenty minutes for the missing mass to return, and it did so in sudden jumps—rather than a smooth, gradual change as we might expect. In this new science, gravity and time are interconnected. Ultimately, all atoms are vortexes of motion within an energy most people call gravity, and which we are calling the Source Field.

Let’s look at a whirlpool in a stream of water for a minute. Does any of that water actually disappear when it goes into the whirlpool? What happens to the water after it shoots through the vortex? Does it shift into some parallel reality, never to return? Of course not. The water is obviously still there in the stream, and it keeps right on flowing along. How does this apply to the earth? Simply put, the energy flowing into the earth must also flow back out of the earth. Gravity, as a downward force, must also have an upward force—and my favorite name for gravity’s counterpart is levity. The Source Field, or gravity, rushes into our planet to create all the atoms and molecules on earth simultaneously—but it still has to keep moving. Once this same flow of energy streams back out of our planet, it has now lost some of its momentum—so it would be traveling a little more slowly than it went in. Once you understand this, you will see there may be an upward-pushing force from the earth that is in a constant tug-of-war with the downward-pushing force—and the downward force only wins by a very small amount. If we did not have the upward-pushing force to balance everything out, we would very likely be instantaneously crushed flat by the pressure of gravity.

Atoms and molecules are nothing more than vortexes within gravity. In Larson’s model, there are only three real dimensions—and in this absolute reality, space and time are one and the same. You then have two parallel realities where the space in one reality creates the time in the other reality, and vice versa. There is a constant, flowing exchange between these two realities going on within every atom. When an atom pops over into time-space, its spinning momentum is transferred over into the fluidlike energy within the parallel reality—and it is no longer affected by gravity in our own space-time. Gravity now moves right through that area without pushing on the atom anymore. However, if the atom (or vortex in time-space) starts losing its speed and momentum, gravity pulls it back over into space-time. The full transition can take fifteen to twenty minutes in a larger object with many atoms, as we saw in Kozyrev’s experiments. Interestingly, the renowned mathematician and physicist Roger Penrose said in a 1997 issue of
Scientific American
that gravity triggers the transition between a particle and a wave at the quantum level.
¹
Dr. Hal Puthoff calculated that there was a direct relationship between gravity and the trembling motion within all particles the Germans dubbed
Zitterbewegung.
²

Back in 1982, Princeton scientists had discovered that electrons become fluidlike when kept at super-cold temperatures and zapped with the world’s most powerful magnet. This fits very nicely with our model.

And here’s my favorite part of all. Theoretically, an atom in space-time gets pushed on by gravity—but once an atom pops over into time-space, it gets pushed on by levity. This means that within our reality, that atom now has thrust . . . as long as it is still bound together with other atoms that have not yet popped over. Therefore, if you want to get an object to levitate, you would need to bring its molecules to a point where they are half in and half out of our own three-dimensional reality of space-time. That way, the levity force can then balance out against gravity—not unlike how you can float perfectly still underwater by controlling how much air you hold in your lungs. If you push an object too far over into time-space, it will dematerialize. Then the same force that was causing it to rise up in our reality will now make it fall down in the parallel reality. Gravity takes over—but in a totally parallel reality. This may work in a manner similar to a Möbius loop as you pass between realities.

Nature uses these principles all the time. The DNA molecule stores photons of light, and it appears that this same flip-flopping at the lightspeed boundary is what allows DNA to easily exchange energy and information between space-time and time-space—between our physical body and our energetic duplicate. In the remaining part of this chapter, we will explore gravity-shielding effects occurring in air vortexes (tornado levitation), water vortexes (trout rising through vertical waterfalls), plant fibers (the secret ingredient involved in sap flow) and insect wings (to keep certain large insects airborne and prevent collisions with other insects)—not to mention the flow of electromagnetic energy, once properly understood. And that’s not all.

Let’s start with tornadoes. The conventional explanation is that the levitation inside a tornado is caused by air suction—and that certainly should account for some of what we’re seeing. However, once you add in other curious effects that have been documented, even on government NOAA Web sites, we can no longer be so sure that this is the only cause of the levitation—or even the main cause of it. There are many cases of people, animals, objects, even entire homes ending up inside a whirling tornado and transported large distances without being damaged
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—where the fiercely rotating air should have torn them to pieces. Many matter-blending effects have been documented as well. The first time I read about this was in a technical paper by Dr. Alexei Dmitriev. The story that jumped out at me the most was of a clover leaf that had been found pushed into a stucco wall, during a tornado—as if the wall had become soft and spongy.
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At the time, this was a mystery to me—but now it all makes sense. Another good example was of an Oklahoma tornado in 1942 that tore one of the wheels off of a car, while leaving the rest of the car undamaged.
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I realized that if the lug nuts on the wheels had become soft and liquidlike, the levity force could then pull the tire off the car and lift it into the air quite easily.