Author Topic: Gradient-free ionization  (Read 2216 times)

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Gradient-free ionization
« on: February 20, 2009, 20:28:47 pm »
This is my interpretation if figure 8-10 , no idea how this is wound in reality or dimensions , it is based on the bobbin of figure 6-1...

It is also my interpretation of Stans colorado part 9 and 10

It is a very ugly drawing and ruff draft , but it is my idea and I would like you to ask permission before recreating, and also be cautious and consult a professional , this is "at your own risk" .

I will not experiment with this yet , I believe the injector is gonna be easier and more safe than this to actually feed to a motor , it seems dangerous ... I would create somekind of Quenching and feed the tube with ambient air picthed upwards @ a certain angle .

I believe the amp inhibiting coil should be a large coil


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« Last Edit: February 21, 2009, 00:07:29 am by Dankie »

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Re: Gradient-free ionization
« Reply #1 on: February 21, 2009, 01:04:11 am »
http://www.bibliotecapleyades.net/bearden/ferdelance/s18.htm

An artificial potential is deterministically patterned spacetime stress, made by opposing E-fields and/or B-fields so that they sum to vector zeros in a special pattern.

The resulting zero-summed envelope has no EM force field, to an external observer/detector.

However, the infolded E-field and B-field vector components still exist and act. They may dynamically vary, so long as their summation is always kept to zero.

The simplest variation is to vary all their magnitudes at once, by the same degree. In that case, each one comprises an "EM wave." However, the summation of this cluster or "locked group" of waves still exhibit a zero-E and zero-B field to any external observer/detector. In other-words, to an external observer, one now has a varying wave of pure spatiotemporal stress, but one which has a deterministic structure. This is a scalar EM wave, or electrogravitational wave. It is also an alternating current of specific scalar pattern.

Varying the stress of spacetime locally, curves it locally. This violates the conventional assumption of restricted general relativity that local spacetime is uncurved (is a Lorentz frame).

By use of scalar EM waves with deliberate substructures, one can engineer Bohm’s "hidden variables" so that quantum mechanics becomes deterministic rather than statistical. This is a drastic change to the common (Bohr) interpretation of quantum mechanics.

And Einstein’s intuition that God does not play dice with the universe turns out to be correct after all.

Since physicists haven’t seen where the real game was being played, it has all seemed bewilderingly statistical to them.



http://www.bibliotecapleyades.net/bearden/ferdelance/s23.htm

We now visualize the formation of waves of pure stress in the spacetime medium (in the vacuum). arThese we call scal EM waves, Tesla waves, electrogravitational waves, longitudinal EM waves, waves of pure potential, electrostatic/magnetostatic waves, and zero-vector EM waves. All these terms are synonymous. Each sheds its own particular light upon the nature of these waves or of their original discoverer, Nikola Tesla.

We use a gedankenexperiment, or thought experiment, in which we can be "perfect."

Thus we have two single-frequency EM sine waves whose E-field components are shown on the slide. The two waves are of the same frequency, traveling together in the same direction, and superposed 180 degrees out of phase with each other.

In this case, at any spatial point, the summation E and B fields are vector zeros.

However, if we plot the spatiotemporal (vacuum) stress induced by the wave, we see that it constitutes a sine wave, with compressive stress in one half cycle and tensile stress in the second half cycle.

Rigorously this defines a "longitudinal" EM wave -- or what Tesla called a "sound wave in the nonmaterial ether.’’

Also, rigorously it is a gravitational wave, for it is a wave of the curvature of spacetime (nonlinearity of vacuum) itself. That is, what is changing in the wave is the vacuum stress, or intensity of the virtual particle flux of vacuum. That is identical to changing the curvature of spacetime. In one half-cycle, spacetime is curved positively. In the second half-cycle, spacetime is curved negatively.

Since the increase or decrease of the intensity of virtual particle flux (vis-a-vis the ambient vacuum’s virtual flux intensity) represents electrical charge, then in one half-cycle negative charge is represented, and in the other half-cycle positive charge is represented. This directly explains the "positron-electron pair" representation of an electromagnetic photon -- the "photon" being one wavelength.

In one half-cycle, time moves slower. In the second half-cycle, time moves faster. Thus scalar waves can also be considered to be "tempic" waves (to use Wilbur Smith’s term), or oscillations of the rate of flow of time itself, about the ambient rate of time flow. Since these oscillations are variations in the curvature of spacetime, then they represent gravitational or force-generating waves, when coupled to a mass.

Variations in the rate of flow of time produce force, just as any other type of curvature in space time does