Goal of recent experiments

The end result of the recent magnetic experiments:

When two dissimilar materials come in contact, a junction is formed (conventional physics). This is the diode junction, and there exists an intense internal electric field. So when two dissimilar materials are in contact, a junction is formed. Such homemade diodes do not make good non-linear diodes for a lot of technical reasons, but still the internal electric field exists in such homemade diodes.

Piezos also have an intense internal electric field. So there is a correlation between diodes, piezos, and the recent experiments that are homemade diodes. It is believed that this internal electric field produces an effect that is responsible for the DC current & voltage. It was learned in the years of diode experiments that the DC voltage was relative to the diodes resistance; i.e., twice the resistance = twice the voltage. The reason is seen in the mysterious 10pA of current. Voltage is R * I, and if I is constant, then voltage is relative to the resistance.

Most of the homemade diodes produced hundreds of milli volts. The current was typically in the low nano volt region to high micro volt region, but this was initial current, not the stabilized *DC* current. For example, the last setup initially produced over 500pA, but the longer it was connected to a load, the load the current dropped. This morning it was down to 79pA, and is still dropping. It's still unknown if it will stabilize at 10pA or continue to drop. It could go far below 10pA, which was seen in countless diodes due to being disturbed, but these diodes would go back up to 10pA when left undisturbed.

The 10pA may not sound to good for most people, but from my point of view it's very important! The reason being is that I the diode and piezo represent the *fundamental* component. So this allows us to study the fundamental effect. Normally when such components are connected in parallel the current remains at 10pA, very unusual indeed! So the goal would be to find a way of getting such fundamental components to go beyond 10pA. This proves it's not due to electrochemical reactions. Paralleling electrochemical batteries results in more current.

So far it appears the size of the diode or piezo is unimportant. I have a diode with a junction that's ~ 1cm x 1cm square that produces no more DC current than a microscope diode. The homemade diode that's ~ 10 cm square appears to be no better. This means that when we figure out how to *isolate* each component to go beyond the 10pA limit, then microscopic particles (components) can be used to make a normal size battery that produces voltage & high current. This is probably the result of Marcus Reid & John Hutchison are doing. IOW, part of the materials used in their crystal batteries is somehow isolating the individual particles to allow the current to go beyond 10pA.

There needs to be some form of *isolation* between each fundamental particle, and that's the type of experiments I'll be doing. Maybe it needs to be Johnson noise isolation. Maybe it needs to be high frequency temperature fluctuation isolation. Maybe it needs to be magnetic or electric fluctuation isolation. Who knows, but working with fundamental components is important.

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