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down would create a ripple in the flow of time—a wave—that could be measured two to three meters away. This is just like what we would see if we were raising and lowering the weight underwater—there would be ripples we could then measure at a distance. Some time after I first read about this in 1999, I realized that this meant the Source Field, which exists all throughout space and time, must behave like a fluid—and this became the key to solving the mysteries of sacred geometry, as we will soon see—not to mention the pyramids.
    Kozyrev found that these ripples could travel right through solid brick walls as if they weren’t even there. 12 This has led most Russian scientists to conclude that the flow of time has a much closer relationship with gravity than it does electromagnetism—as I said before. Electromagnetic energy can be shielded—but the force of gravity holds you down equally as well inside a brick building, or a lead-lined cage, as it does outside.

Nonmechanical Detectors
    So far, we’ve only studied the mechanical detectors Kozyrev developed. He also found other nonmechanical ways to study the flow of time as well—meaning these were methods that did not use any moving parts as we would normally think of them. The simplest of these detectors was heat.
    Every atom is filled with a constant frenzy of whirling movement, which scientists call spin. When an object heats up, there is an increasing amount of chaotic, unpredictable movement in the atom—which eventually causes it to give off a glowing red, yellow or white light. Heat creates random, unpredictable, chaotic movements that disrupt the free flow of the Source Field at the quantum level—reducing coherence. On the other hand, when an object cools down, there is less resistance to the quantum flow, and it will move faster and more smoothly. This explains why superconductors need to be kept at super-cool temperatures. The lack of heat creates a lack of movement that would interrupt the flow of electrical current. Kozyrev thus realized he could measure changes in time with an ordinary mercury thermometer—kept in an environment where the temperature was otherwise being held constant.
    Kozyrev also found that his experiments worked best in the first half of the winter. In the summer, the heat in the surrounding area seemed to have a scrambling effect on the overall flow of time—and this made it difficult or even impossible for any of his experiments to work properly. The increase in heat reduced the coherence in the Source Field.
    Kozyrev also found that the flow of electricity could be affected by changes in the flow of time—and this was the same effect that the Global Consciousness Project was apparently detecting. Professor Simon Shnoll also used electrical current as one of his tools to detect changes in the flow of time. Kozyrev found that tungsten metal was extremely responsive to the flow of time. Tungsten’s electrical conductivity could be permanently changed if you zapped it with a strong enough time flow. Another time flow detector was a quartz crystal. When you see the word quartz on a watch, that means there is a crystal inside of it with electricity running through it. The flow of electricity causes the quartz crystal to resonate at a speed that is steady enough to keep solid time. The crystal in a watch is shielded from Source Field influence, on a component level, by methods we will discuss below. For that reason, we normally do not see any changes in how a quartz watch keeps time—and the scientists who built them that way probably never realized what they were actually doing. However, if you blast a nonshielded quartz crystal with a strong enough time flow, its vibrating speed will change—and Kozyrev could measure this in the laboratory. Again, this change can be permanent—showing that the molecular structure has actually changed.
    Yet another interesting nonmechanical detector of the time flow was the thickness or