in-wire sp2 and sp3 carbon treatment

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Atomic Carbon treated cables and wires

Several tests have be done in our static reactors. One is the treatment of cables and wires which have - under their insulation jackets - copper strands. So all copper wires and strands were still in their insulation jacket while processed.
Different type of cables and wires were introduced in or connected to plasma reactors. Some reactors were filed with some Kt Liquid, other were only filed with pure plasma (a Kt Liquid moisture). No additional external energy sources - like EUV from arcs, magnetic fields from solid magnets, electrical current, etc. - were used.

Two kind of treatments

Dynamic plasma reactor in steel for the generation of power

This static reactor has in the wall different type of electric/telephone cables mounted.
Below image shows small telephone wires (each having seven copper strands) inserted in a cola bottle reactor. In these tests only a Kt Liquid moisture is added. After this the reactor is closed and the deposition process starts.

Dynamic plasma reactor in steel for the generation of gravitational effects

Results after processing

Dynamic plasma reactor in steel for the processing of matters

After expose in static Keshe reactors it has been found that all copper wires and all strands - each - were fully covered by atomic carbon.

This means that the carbons atoms, entering by one end of the cable, were deposited on the copper surface of each wire and strand.

The carbons atoms, entering by one end of the cable, were deposited on the copper surface of each small wire, and in these small wires on each strand.

There are indications that the deposits are fullerenes, a combination of sp2 (graphene) and sp3.

Spectacular is that each strand is completely insulated from the other strands in the same insulation jacket.

The insulation material (polymers) itself is not altered or damaged by the processing, only a slight difference in color is observed. This is the proof that the process is not a chemical reaction,

NEW INSULATING AND CONDUCTIVE PROPERTIES

Although the strands are in direct contact with each other surface, they are fully insulated from each other by the atomic carbon layers. This is proven in tests - at room temperature - with multi-meters and physical tests with batteries (9V) and lighting, were current was conducted through wires which were directly twisted with each other.

Dynamic plasma reactor in composite plastic for the generation of motion in space and the processing of various matters

This all means that new proprietary type of wires have been developed, which can co-conduct several strength of current at the same time through their different strands, and this will mean a revolution for all kind of electric and electronic designs.

This approach can also be used for the design of transistors and integrated circuits. In example, surfaces with only a few number of atomic carbon layers - like in sp2 (graphene) having ballistic conductive properties - can be mounted directly on each other while they are still insulated from each other. With technics like etching special circuits can be made.

Ir. Keshe: "It is clear that we have found a number of new principles of atomic interactions and reaction on atomic level, which were unknown till now. We developed methods to generate new type of processes in our reactors, and the coverage of wires which are still in their insulation jacket is just one of the industrial application we see. When you are working on atomic and nano level you are thinking in other sizes, let's say if the carbon atoms would have a size of ping-pong balls then the insulation material - which we normally think as being very tight to the copper strands, could have gaps like tens of meters wide from the copper strands themselves, so the carbon atoms can travel easily through and being deposited on the free copper atoms which attract them. Our method is that we mount full telephone cables in the wall of our reactors leaving the rest of the cable outside the reactor, and the cables acts like exhaust pipes to transport the atomic carbon while depositing them on the copper. This is a process at atomic level, not a chemical process, since the insulation of the wires is still intact."

We can apply this amazing wire treatment on atomic and nano level immediately on industrial scale. The process is quite simple. This new achievement confirms our previous findings that carbon sp2 and sp3 can deposited on various substrates and objects at room temperature and normal atmospheric pressure, and this, without complicated systems like the traditional arcs treatment. We can provide industry with all kind of nano-materials at very competitive prices.

Of course the methods and applications are under patent pending, since they will change - yes simplify - a large number of industrial processes, and this not only on nano-scale. Next to that, the proprietary approach developed by Ing. Keshe makes is possible to create self-sustaining energy production, which will lead to new type of electric generators."