The objective of the process is to produce pure electrified water
containing a high percentage of positively charged silver ions - without the formation of any silver compounds.
This is best achieved by using low, gentle direct current (DC) that is controlled.
To emphasize the importance of low, controlled current, one merely has to look at nature.
Colloidal minerals as they occur in nature. in fresh fruit and vegetables,
are produced slowly, over time, with electrical currents running in the nano or pico amperage range,
(i.e. billionths or trillionths of an ampere).
When the synergy has been established during the course of the process,
the correct magnetic fields are set up and remain constant.
This ensures the correct molecular structure of the water(Refer Part 3 - Creating Structured Water)
in highly organised hexagonal chains that surround the positively charged silver ions.
This is critical, as it ensures the bio-availability, stability
and efficacy of the end product.
The above factors are all inter-related and critical to
the correct production of electro colloidal silver.
The slower and more gentle the current, the purer the final product. Obviously, one needs a practical time-frame in order to produce electro colloidal silver, but one could, for example, set up a system to run over a week at extremely low current and you would have electro colloidal silver of exceptionally high quality.
Pure silver will not oxidise. That's why it's a noble metal.
At left is a pure silver rod in distilled water, which has been in this jar over the last four years. The initial conductivity reading was 0.5 µS/cm.
No oxidation has taken place, yet the conductivity is gradually going up. It now reads over 10.0 µS/cm.
This is an example of the slow art of producing electro colloidal silver.
(The boys in the lab can hardly wait to have a
sip!)
Silver Rod in a Jar:
one of the tests in our Research & Development
centre
It is a well known scientific fact that when you exceed the voltage and current that water molecules can withstand
(i.e.electrolysis), the molecules begin to break up - causing excess hydrogen and a low pH. In other words, the solution becomes acidic - and the bonding and compounding of elements takes place.
This can easily be identified by the visible formation of clouds at any stage during the process. Hence the discolouration of the water (gold, yellow, brown etc.) This is an immediate indication that the electrical potential of the positively charged silver ion is
non-existant.
What are you seeing when you see "clouds" or "the tyndell effect"?
A silver ion is many thousands of times smaller than a human cell or even a virus. Obviously they are invisible to the naked eye - so, when you consider that it requires a transmission electron microscope using a specialised process to identify these silver ions, what are you seeing when you see clouds???
An example of the electrolysis process commonly used in generator equipment today.
Wisp
of cloud forming off anode
First stage in breakdown of the water's molecular structure.
The stronger the current, the more readily silver will bond with oxygen and other dissolved salts and minerals to form silver compounds as well as clusters of silver atoms and larger silver particles. Excessive current in relation to surface area of silver and volume of water (as indicated in this photograph), is an immediate indication of electrolysis taking over.
The water molecules (hydrogen & oxygen) are being broken up - leaving an excess of hydrogen and creating a low (acidic) pH level.
The structuring of the water is incomplete.
Whatever charged silver ions remain, are now vulnerable to outside influences like air, light and magnetic fields.
The electrical potential of the silver ion has been lost.
In an attempt to produce a pure colloid, this process (electrolysis) was used in the early decades of the 20th century, Unfortunately, in those days the process was misunderstood, much as it is today. As a result, stabilizers were introduced such as mild protein and hydrogen peroxide (H2O2).
Note: Even a 9 volt battery has a capacity output of 500 milliamps (half an ampere)! In relation to the surface area of silver being used in most systems today, this is 499 milliamps too much!
