Manipulating the ORMUS elements
The ORMUS elements differ in a fundamental way from their "ordinary" metallic
counterparts. In a sense they can be considered to be parallel to the metallic elements on the periodic table. What
differentiates this form of matter from "ordinary" matter is that the ORMUS elements are in a high spin state. This
means that the atoms are spinning more rapidly than ordinary atoms. This high spin pulls the electron cloud in
toward the nucleus of the atom, sort of like an ice skater pulling her arms in to increase the rate of her
spin.
As these electrons get closer to the nucleus they pair up into what is called "Cooper pairs" of
electrons. (The Cooper pairing phenomenon is named after one of the gentlemen who received a Nobel prize for its
discovery.) These electrons, when they are Cooper paired, are no longer available for ordinary shared electron
bonding between different elements. This means that they can no longer form ordinary chemical compounds.
Methods have been developed to convert metal to ORMUS. In one way or another these methods
induce the high spin state and the Cooper pairing of electrons in the individual atoms or diatoms. It is also
possible to convert ORMUS to metal using different methods.
Each of the elements, that can be transformed this way, keep their individual elemental
properties through the transition from metal to ORME and to metal again. Some of these properties are common to
both the metallic state and the ORMUS state. For example, the m-state rhodium gives water a sticky feel. This is
also true of the metallic form--rhodium hydroxide. Also, rhodium seems to be useful as a catalyst in the ORMUS
state and in the metallic state.
Because these elements hold on to their electrons so tightly the ordinary spectrographic methods
of identifying them simply don't work. The only way we currently know to identify them is to run a spectrographic
analysis on a candidate ORMUS sample, then convert it metal and run the spectrographic analysis again. If the first
spectrographic analysis shows no metal and the second shows metal then we have identified an ORMUS
element.
Though these elements don't form chemical compounds which are bound by electron sharing, they do
seem to be involved in chemical compounds in some special ways. I believe that they should be suspected to be
present in any chemical compound which cannot be synthesized. Chlorophyll would be an example of this type of
compound. I understand that the "secret" ingredient in chlorophyll is the ORMUS form of copper.
Since these elements are not bonded by shared electrons, how might they be bonded? I know of two
types of bonds which might apply.
All of these concepts are discussed in greater depth in Hudson's lectures and in Gary's article
titled "Paranormal Observations of ORMEs Atomic Structure". These resources can be found at:
http://209.17.143.141/ormus/
Superconductivity is a property of certain substances which are in a special quantum state
called a Bose-Einstein Condensate (BEC). A BEC is a large group of atoms which behave as a single atom due to their
being in a common state. In the case of the ORMUS elements, their superconducting nature creates an energy field
around each atom. This energy field is called a Meissner field. A Meissner field resonance couples individual ORME
atoms to the point where many atoms can act like a single atom. This resonance coupling between ORME atoms allows
you to perform a sort of shadow chemistry on them.
It appears that there are varying degrees of ORMEishness. An ORME diatom can have all of its
electrons paired up or it can have only a portion of its electrons paired up. If you have an ORME diatom which is
partially paired this will leave some electrons available for conventional electron bonding with other elements.
This ORME diatom will then have one foot in the ORMUS world and one foot in the metal world. You can use these
partial ORMEs to manipulate the full ORMEs chemically.
Imagine that you want to collect all the loose male dogs in your town. It might be difficult to
chase them all down individually but there might be a simpler way to do this. You could find a female dog in heat
and use a known property of male dogs to collect them. You would put the female dog on a leash and lead her through
town and pretty soon you will be leading all the loose male dogs around too. These male dogs are not on your leash
but they are attracted to the female dog and they will follow you because you are leading her.
In a similar way we can do chemistry on the partial ORME and use the partial ORME to lead the
full ORMEs around.
There is another type of bond which we have seen in these ORMUS elements. Since these elements
are stimulated by movement in relation to magnetic fields, and since magnetic fields are everywhere, they seem to
seek situations where they are protected from movement in relation to magnetic fields. Any type of tight space will
limit their movement in relation to magnetic fields. This principle can be used to manipulate them. You can move a
fluid containing the ORMUS elements in relation to a magnet and provide a tight space for them to go to and thereby
trap them.
We believe that the simple methods to chemically concentrate the ORMUS elements from water that
are described in the ORMUS document at http://www.lyghtforce.com/WhiteGold/ormus.htm also use this second
principle. The sodium atoms provided with the lye appear to form a three atom cluster or a triangle. We believe
that this triangular molecule provides a nice tight comfy inner space for the ORME to hide in. Similar ring
molecules made of carbon, oxygen and chlorine have also been used to trap and chemically manipulate the ORMUS
elements.
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