Phonon Conversion of Ag to Au

a dimensional formation

Personal Note.........

This document is the first phase of technologies that allows for the formation of new elements by select researchers, scientists, technicians and hobbyists. In the first part of this paper, one can safely convert a micro amount of silver (Ag) to gold (Au). Next is the theory has to 'why' the process works for some and finally is a procedure for the production of Au in its pure state that requires laboratory apparatuses.

General

In the formation of Ag (or other elements) from a dimensional reaction, the conversion will occur without excess energies or nuclear signatures. By heating Ag to a temperature of 43.2 ^oC. The principle is straightforward and simple without toxicity.

By utilizing a heat source that is stable and capable of heating in the range of 100 => 120^oC assemble a vessel similar to that shown in Figure 1.

Allow the temperature of the silver to stabilize at the pre-mentioned temperature. It is important that you measure the temperature of the silver and not that of the sand. The function of the sand is to provide an even influx of temperature to the entire area of the silver and it provides an excellent insulator.

The temperature of 43.2 ^oC is optimum under ideal conditions. However, it is possible that the temperature may vary within the statistical limits shown in Table 1. When the temperature is exact for the reaction the silver with become endothermic. This means that the temperature will be slightly greater than that of the surrounding sand. A point of interest - this reaction is the same as observed in the working Cold Fusion cells of the past. The scientists were not observing a low energy nuclear event, they were observing an inter-dimensional phenomenon.

To achieve maximum convergence of Ag to Au will depend on the dwell time at resonance temperature. To date, visible conversion of Ag to Au has occurred in as little as six hours, with 2% conversion taking up to 24 hours.

The reaction is safe and produces no toxicity's.

Click Here for a procedure to determine if procedure is working.........

Theory

The conversion of one element (specifically one isotope) to another through a dimensional reaction occurs under select conditions of phonon resonance. Dimensional phonon resonance occurs when the space occupied by one isotope is exactly the same as that of another isotope in its rest state. This event only occur under the following two conditions:

the expansion of an isotope by heating; or,

the contraction of an isotope by cooling.

Due to the natural characteristics of elemental properties, this event is extremely rare and one can only force the event under select conditions. To determine the phonon resonance of an isotope, it is necessary to apply the following formula:

whereas, d - Density in gm/cm³

Na - Avogadro's Constant

m - mass

By determining the inverse, one will observe the linear atomic spacing.

Since the resonance frequency and spacing is required for all isotopes, the calculations for most isotopes may be reviewed in the attachments to this document. Following is an abstract of the data:

When an element is heated or cooled, the atomic spacing will change proportionally to the cube of the product of the temperature (increase/decrease) and the expansion coefficient. To understand, following is the mathematical model for determining the linear spacing in reference to temperature:

whereas, t - temperature increase

St - standardized temperature

Ec - expansion coefficient

To place this in perspective, to determine the exacting temperature for a dimensional phonon reaction to occur, requires knowing the starting element (specifically the isotope of the starting element if more than one) and the element to be produced. Once this is known, you can apply the following formula:

This will provide the temperature required within statistical probabilities. A statistical probability deals with the least significant digit (LSD) of each variable. In the case of phonon resonance, this is limited to the density. For example, the density of Ag is 10.50 gm/cm³. Taking that the accuracy is ±1 LSD, we can establish a variable range by applying the following:

Or, +/- 0.0009524

To place the mathematics in perspective, following is the calculations for the conversion of Ag¹⁰⁷ to Au.

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To find the most logical profile requires determining the basic phonon frequencies of all of the stable isotopes.

Conversion of Al to Au

The conversion of Al to Au is an absolute application of dimensional science. In this reaction, Au (gold) is produced in its ultra-pure state on a continuous basis. This procedure may be utilized for most elements. The basis of this dimensional occurs in the collection of atomic size particles that form near the resonant metal (in this case aluminum). Due to the size of the particles they appear in what normal chemistry would consider a gas phase. The targeted element (isotope) forms in its singular state and due to the lack of energies present. There are insufficient energies to bind the atoms into a colloidal state. This being the case, an apparatus similar to the following is required.

In the production of gold from aluminum, the ideal temperature is 302.9 ^oC. These temperatures are optimum for the Al (the Al must be allowed to come into equilibrium with the furnace). Once resonance is established, production is continuous. The Au is captured in the water as it is removed from a negative pressure applied to the furnace established by the vacuum pump. However, please be aware that Al will also convert to Ag¹⁰⁷ at a temperature of 283.7^oC. To understand this, the following chart is supplied:

As you can see, as the aluminum reaches the phonon resonance of Au it passes through the resonance of Ag. Due to the atomic spacing, Al will not form any other element near this temperature range.

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Conclusion

All of the procedures listed were confirmed by independent laboratory testing..

Additional Procedures for the production of Ag and Au

addendum to:	Phonon Conversion of Ag to Au
	a dimensional formation

At the time of printing the Phonon Conversion of Ag to Au, the genesis mapping of elements was not complete. Based on the above, the following allows the other potential formation patterns for Ag and Au.

For additional information refer to: Isotopic phonon spacing.htm

Note: Numbers are representative in the degrees Centigrade.

Please note a significant point of interest. This procedure is nondescript. As easy as zinc, aluminum, titanium or silver converts into gold, so does gold convert into titanium and silver.

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Gold Detection in Silver Transformation

To determine if the procedure is working, take either the entire piece under test or a small piece by drilling out a sample and place it in 15% nitric acid (HNO₃) and distilled water. Do this at extremely low heat. If Au is present, it will appear as small black particles floating in the nitric solution. The larger the quantity of particles, the larger the quantity of gold that has transformed. [NOTE: Characteristically, all silver has at least a trace amount of gold present.]

on. The larger the quantity of particles, the larger the quantity of gold that has transformed. [NOTE: Characteristically, all silver has at least a trace amount of gold present.]

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