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www.hereticalbuilders.com

A Study of

Dr Stiffler's

Spatial Energy

Coherence

By Inquorate (aka Ben Brandwood)

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Acknowledgements

Special thanks to Dr Stiffler for a trail of breadcrumbs. Without whose continued hints I wouldnt have worked this out. Thankyou for releasing the culmination of a

life's work. The greatest respect.

Thankyou to Frank Znidarsic whos paper and writings were eye opening to say the least.

A tip of the hat to all the brilliant contributors at www.hereticalbuilders.com

including but not limited to Gravock, Arathu, Tecstatic, Mikrovolt, Reason1st,Lidmotor, Arioch and our host, Ted.

http://www.hereticalbuilders.com/http://www.hereticalbuilders.com/

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A Piece of WireTo understand the Spatial Energy Coherence (SEC), one has to reinvestigate the simplest of things. So, lets take a look at the simplest electronic component; a length of wire:

A piece of wire is of course metal;

It transfers electrons and heat very well;It can be considered an inductor;

It is also one plate of a capacitor - the other plate being the environment.

Fairly simple, right? But interesting things happen when we change the potential of the wire,which we will investigate by looking first at a fluid analogy: the common garden hose.

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When we change the electrical potential of the wire, we essentially force the electrons to lineup; ready to jump to the next atom.

This creates two pressure waves, just like in the hose analogy. The jostling alone, as well asrandom atomic movements, will give off photons.

We can consider that mostly, the electrons will move to the outside of the wire to the area of least pressure, (except in the case of a coil of wire, as we'll see later) at the speed of quantumtransition, 1.094 million meters per second.

This will affect the surrounding environment in the very least by causing alignment of ionsperpendicular to the wire as the pressure wave travels along; at the speed of Quantumtransition, which happens to be the speed of mechanical vibration (sound) in the nucleus of anatom:

1.094 million meters per second

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An InductorSo, what happens when we coil up that piece of wire to make an inductor?

The above coil would probably have an srf of 30mhz; a multiple of one of the base srf's, if stimulating pigtail c with a one wire from a signal generator.

Why?

Lets go back and see what's happening.

Feeding the end of pigtail 'c' with a sine wave from an oscillating circuit will cause the change inpotential / electric stress to travel to the inductor.

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The inductor wire is electrically linked to the coil next to it, and the wave of electrical stresstravels over the coil, to the end of pigtail 'a' and will consider for now that it terminates there.

Stimulation with any frequency not the srf will be impeded.

If the strength of the rf field were measured and mapped out, it would look like this:

Which is very much like the motion of a spring tied at one end.

With the spring, it is atomic elasticity of the steel that sustains the oscillation.

What will sustain the copper wire oscillation if we shake it at 1/4 it's srf?

Really, think about that..

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Wherever the source of the elasticity sustaining the damped oscillation, it comes from theenvironment, which means the losses come from the coil itself; which produces heat and rf, etc.

We could then represent any coil like this:

With its ideal lossless mirror in the environment.

- the source could be random atomic and quantum impacts (heat and pressure),

- it could be the earths magnetic field

- it could be the quantum virtual particle flux, or

- something else that is elastic, rigid and kinetic.

That, we know. Whatever it is, when we push, it distorts and pushes back. How does theenergy get back into the coil from the environment?

Electrostatic? Electrical strain perpendicular to the coil may be entering the inter-windingcapacitance of the coil.

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Considering that the wire creates a longitudinal electrostatic pressure wave a short distancefrom the wire we see what happens in a coil.

As the pressure wave travels through the inter-winding capacitance, it may also cause amovement inside the coil windings.

If this were to be so, then the pressure in-between the windings would build, and the surface of the wire would no longer be the place of least resistance for the electrons. Instead, they wouldaccelerate up the wire, perhaps adding to the intensity of the pressure wave traveling along thecoil.

This would account for the distribution of rf field strength toward the end of the coil not beingstimulated by the oscillating circuit. This would move the space around the coil.

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The Avramenko PlugHow does energy travel two ways along the wire, below?

It cannot.

The wire can deliver mostly potential; add the avramenko plug and some current will flow backand forth, but to where?

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Negative ResistorsSilicon doped semiconductor components all have a reverse breakdown voltage. Zener diodesall take use of this effect as their main principle.

Some components like the kspZnZZZZ, in 4148, mpsA06, have regions of negative resistancethat, like the tunnel diode, incorporate Quantum tunnshine in how they break down.

All semiconductors have a no-go region where there are places available for the electrons - thespots are filled.

Basically, electrons can jump from the left to the right by borrowing energy from the universeand paying it back really quickly (Heizenbergs uncertainty principle). This is quantum tunneling.As more and more electrons are added, they get crowded, and soon would be stuck in one spot.This would violate the uncertainty principle, so the breakdown voltage lowers as more electronstunnel over the barrier.

This of course, requires a quantum transition, which happens at 1.094 million meters persecond.

Feedback; lockstep

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When we blow through a straw, the particles tend to move in straight lines. When we suck, theparticles of air move from widely dispersed areas. This is true of the oscillating coil moving theatomic matter also.

So, if we were to try and synchronise the pulses to the coil to the backdraft, we would need to

amplify the particles movement to feed that signal to our negative resistance based oscillator.This would keep our oscillator locked in to the oscillation of the coil to the environment.

Luckily, we know that the ultra sonic vibrations being caused (Phonons) tend to amplify in somemetals, like Aluminium.

This signal can be fed to our pn or npn junction so that it's reverse breakdown voltage level isreached at the same time that the longitudinal pressure wave reverses or contracts; the phononwave travels to the crystal silicon junction as a supersonic vibration which may assist thequantum tunneling in that moment;

This means the circuit vibrations synchronise with the atomic lattice vibrations.

The 3 rd OscillatorWhich brings us to what happens at the battery side of the SEC boards.

The battery terminal negative has lots of hv present on it because the metal is also vibrating.Depending on the dimensions of the battery plate, (just very wide wire), the battery will want toresonate with the environment at a particular frequency.

Match the srf of the coil and load and the frequency which the oscillator itself is oscillating atand all three wave emitters will be in sync.

Essentially, when tuned this way, the circuit just adds a little energy to the vibrations of thelattice of energy around the circuit itself, pushing forward and pulling back. Everything in theenvironment becomes part of the circuit.

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PSECJust like a child on a swing, the SEC in passive mode, (a coil on one side and av plug andaluminium block on the other all oscillating together), requires an initial push. Then, the circuitwill build up the environmental oscillation until, one or another component heats or cools andits capacitance or otherwise changes and the circuit will thus come in and out of resonance withthe environment.

Thus, a small constant (natural or otherwise) signal would be preferred, for when another smallpush is required.

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The Atomic MovementsAtoms are constantly hitting each other - well, each others photons, as they exchange forces. If we take our spectrum analyses to any point of randomly vibrating space we see a mish mash of electromagnetic frequencies, like standing in a crowd with everyone talking at once.

But what if the molecules, virtual and real, werent moving randomly but in straight lines,indeed, even in the same direction? That would be like standing in a crowd of people singing anational anthem. The pattern of the compression waves would be very noticeable.

In the special circumstance of every component of a circuit in resonance with every othercomponent and the environment, we see what is usually lost to the background of dissonantnoises: the atoms all moving as one emit noise as one, in multiples of 1.094 mhz.. why?

The journey continues.

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Authors note:

The huge distances between atoms means that the examples and descriptions I have providedare only partially correct.

For the pressure waves to travel at 1.094 million metres per second means that the spacebetween atomic nuclei must be as dense as the nuclei themselves.

There are many holes in this document. I welcome open debate and hope readers will get whatthey need to assist on their journey of understanding.

Perhaps together we can bring a new technology to the world.

For the kids.

In love and light,

Ben Brandwood.