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XHD and EXD are much more efficient for use in power driven orgone generators
than MHD. They require some form of energy input in order to generate energy,
but they are far more efficient at doings so than MHD, which is better for
passive roles.
The density of the matrix determines the amount of orgone resistance that the
matrix affords. It also determines the maximum charge density he matrix will
store, and the minimum charge density required for the matrix to become active.
 Once
the Orgone Matrix Material absorbs enough orgone energy, it reaches a critical
threshold of internal charge density that causes it to begin processing energy.
In the image to the left, the blue lines represent the areas where orgone may
flow through the matrix, and the white flashes represent the areas where energy
is generated or converted form one form to another.
In XHD orgonite, the rate of flow is low because the blue lines are constricted
tightly and have to go around many corners. But the overall energy output is
high because the charge density is high.
In EXD orgonite, the density is so high that it
takes much longer to absorb enough energy to become active. In fact the density
is so high that the material will go through an interesting series of stages
become it is ‘ready to use’. It will first absorb energy , and draw surrounding
energy towards it. As the charge density increases, it will gradually start to
radiate energy out form its surface. Then, it will continue to absorb energy
until it ‘plugs up’ and stops absorbing energy. At this point it will feel very
sluggish and condensed, and the rate of flow through the matrix will be almost
nothing. It may form a skin of frozen orgone or DOR around the surface of the
material. Don’t worry, this is temporary.
Once the EXD material has reached this state, it will respond dramatically to
stimulation. When stimulated, the thin film of highly densified orgone around
the periphery of the material will melt, and the higher charge density stored in
the matrix will discharge into the surrounding area with great energy. If you
are able to see energy, then i can say that instead of glowing, it glows while
its charging, then stops glowing, and appears dark. At this point, flicking it
with your fingertips will cause it to emit bright sparks and long streamers,
almost like lightning bolt. Of course, i am talking about the orgone and not
electrical lighting discharges.
The charge density will remain high from this point, and the device will not
permanently ‘freeze up’ if it is subjected to even a small flow of orgone by
using cascading densities (attaching a small piece of a lower density orgonite
to the EXD. Since orgone flows from a smaller potential to a greater potential,
this will induce the energy to flow from the lower density to the higher
density, stimulating the EXD as it does so. More on that in a future article.
In EXD, the friction is so high that the radionic data encoded into the material
becomes very important. The smaller the metal particles, the more sensitive to
radionic encoding the orgone matrix material becomes.
Once the material achieves enough charge density to become active, it develops
two distinct modes of operation. One mode in which the material is mostly
dormant (without stimulation) and another active mode. In active mode, while the
EXD matrix is being stimulated, the rate of flow radically increases. It flows
many times faster than even lower grades like HD or MHD, while it is discharging
its orgone ‘lighting’. This is a phenomenon i theorize is similar to the cooper
pairing responsible for superconductivity in electronics theory. It appears that
as you go up the spectrum of density in orgone matrix material, you continue to
exchange flow rate for charge density. The higher the density, the more ‘torque’
the generator has, and the lower the ‘rpms’ of the generator are. And so it goes
progressively until you get into microscopic particle sizes.
When orgone matrix material is made exclusively or even predominantly from
microscopic particle sizes, two clear effects begin to emerge. The first effect
is that the material becomes extremely sensitive to radionic encoding. In my
opinion, this is not only because the increased charge density in the matrix
exerts resonant amplification effects on the energy fields within the matrix
(causing weaker signals to be amplified to the point where they are imprinted on
the resin), but also because the random arrangement of millions of tiny
particles serves as a wealth of storage space for radionic data. The multudinous
particles are small enough to be easily acted on physically by subtle
electromagnetic effects associated with orgone fields and eddy currents within
the electrical capacitance of the matrix material, and they reflect radionic
data in their physical orientation as parts of a matrix.
The second effect is that when the charge density reaches a certain critical
threshold, and if the size of the metal particles is small enough, the rate of
orgone flow through the matrix radically increases since when it discharges it
does so more energetically than lower densities. It is as if at some point the
matrix becomes orgone-superconductive.
In this state, the rate of flow increases radically, and since the charge
density of the matrix is so high the charge density remains high despite an
increased rate of flow. You will notice that in the picture with this article,
there are no small blue lines to show the flow of orgone through the EXD matrix,
though these lines appear in the pictures of the other densities. This is
because the energy can only practicably flow through the matrix by traveling a
surge of the white flashes, which are close enough together that they touch and
impinge on one another.
When the EXD is stimulated and it releases its lighting bolts of orgone, the
orgone can travel through the matrix with a rate of flow equal or near to the
speed of the lighting bolt coming out the other side.
So, it tends to put out a pulsed discharge, but the pulses can be made very
short and close together, or long and far apart. When incorporated with
cascading density concepts, EXD can be used to maintain a near-steady discharge.
The pulses can also be focused through a lens to blur them together into a
steady stream. More experimentation to go along this line, and for now that
enough to give you something to think about ;)
Jon Logan
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