This analysis is devoted to the Kap

This analysis is devoted to the Kapanadze coil, which is a close relative of his lesser-known electromechanical
device. The main ingredients for achieving the Tariel Kapanadze (Michel Meyer, Steven Mark, Floyd Sweet,
“SR193”...) effect are Nuclear Magnetic Resonance (“NMR”) which generates the initial fast-moving particles (e.g.
electrons), avalanche particle multiplication (induced transmutation) and a magnetic field of appropriate strength
to confine and guide these particles within a conductive material
It is believed that copper or an alloy of copper or iron are Kapanadze's materials of choice and that material is
used as fuel when it undergoes stimulated transmutation. The reason is that copper has many isotopes with halflife
times spanning from nanoseconds to tens of hours (http://en.wikipedia.org/wiki/Isotopes_of_copper). Copper
isotopes with atomic masses below 63 tend to undergo β+ decay, while copper isotopes with masses above 65
tend to decay in β- mode. Many Copper isotopes have non-zero nuclear spin and hence can be manipulated or
stimulated through Nuclear Magnetic Resonance. However, this statement also applies to Zinc, Iron and many
other metallic elements. Thus these elements, and alloys of these elements such as brass, can also be used as
fuel.
Enhanced β-decay under NMR stimulation is known and actually used in scientific research in so called ‘beta-
NMR spectrometers’ in which the nuclear spin precession signal is detected through the beta decay of a
radioactive nucleus (http://bnmr.triumf.ca/?file=default).
The main task in creating a working device, using these principles is to create a suitable physical layout which
allows an extremely high current in the conductive (or even non-conductive) multiplication disc or ring, to be
excited and fully controlled, and so, not only create torque but also, useful electrical power.
The exact construction of the Kapanadze coil is difficult to infer as the details of the inner geometry and materials
used in the coil are generally hidden. However, knowing the working principles stated above, it is possible to
present an effective, generalised working geometry.
The most logical starting point would be to take the exact geometry of the electro-mechanical device and wrap a
winding, L2, around the perimeter of one or both of the discs as shown in Fig.1. As concluded in the article
below, the current created by the orbiting charged particles modifies and reduces the magnetic field in the discs,
eventually pushing the cyclotron resonance orbit beyond the perimeter of the disc. This results in self-termination
of the pulse. Thus, the multiplication current is self-quenching. There is pulsating current in the disc or discs, and
each pulse is initiated by a short wide-spectrum pulse applied to coil L1. This pulsating current is then coupled
inductively through windings, L2a/L2b and delivered as electrical output.