Gravitation, Repulsion and Doppler
Distortion Systems
Introduction
All matter, from the simplest form to the most complex
is composed vibrating surfaces or strings. Matter naturally vibrates
in unison and/or harmony with all other matter. This matter vibration
creates waves through the ether (the dynamic intersection of three
dimensional space and the higher dimensional surfaces). When separate
matter produces waves, the separate wave patterns create interference
patterns that are the intersections of the emitted waves. One can
visualize two dimensional interference patterns by dropping two
pebbles into a body of water in different places.
These ethereal interference patterns create a higher
ethereal energy state when the waves emitted from matter intersect and
create instantaneous longitudinal (or scalar or fourth dimensional)
waves (see Tom Bearden's research) and the ether naturally attempts to
return to a lower energy state. If separate matter is vibrating in
unisons or harmonies, moving the matter closer together results in a
reduction of interference patterns and therefore moves the system to a
lower energy state. However, it is possible for matter to vibrate in
discord to the
unisons and harmonies of other matter. In this case, the ethereal
interference patterns created cannot be resolved by moving the matter
closer together; rather, interference patterns remain
and increase due to the amplitude increase of the interfering waves
seen as the matter comes together. Therefore, to decrease the ether's
energy state, the matter in discord must be pushed
away to reduce the intensity of the interference patterns and the
created longitudinal waves (see John Ernst Keely's research).
Examples of both unisonic and harmonic attraction and also discordic
repulsion may be observed spectacularly from rapidly spinning black
holes. In these black holes, the emitted wave pitch distortion is
caused by a Doppler effect (the same effect that changes the sound of
a racecar as it races past spectators) due to the core's rapid spin
rate. As a black hole's core rotates, assuming a symmetrical core,
pure Doppler distorted waves are emitted parallel to the axis, while
perpendicular to the axis plane at the equator, the Doppler effect
would seem to be cancelled out. This may happen because, from the
equatorial plane, the rotation effects from one side of the core are
cancelled by the opposite movement of the others side of the core, and
the average of the Doppler distortions occurring would be the unisonic
and harmonic frequencies necessary for gravitational attraction.
Therefore, we see massive gravitational attraction from the equatorial
plane, and massive repulsion from the axis. This repulsion from some
of the more massive holes has been repeatedly shown to produce matter
jets that, according to scientists, "seem" to be travelling faster
than the speed of light. Indeed, not only have solitary black holes
been seen to possess such jets; other rotating systems such as neutron
stars, galactic nuclei, quasars, and even normal stars have been shown
to produce directed and columnar repulsive jets from their axis.
Obviously, this Doppler distortion (rotation and also linear movement)
is a key to antigravity and no doubt is the reason for the universe's
accelerating expansion.
There are also other methods of ethereal matter wave
pitch distortion, such as the high voltage capacitive fields developed
by Townsend Brown (which possibly use similar techniques to those
described below -- who knows, though? We have no access to Brown's
research data), and direct manipulation of matter vibrations using
high harmonics of sonic or electromagnetic waves, but those will be
discussed in future papers.
I believe the easiest method of Doppler distorting
matter waves is to take the example provided by black holes and use
rotating systems. [Using linear movement for distortion would be
theoretically possible for transportation, but if one could reach the
necessary speeds, there would be little need for the repulsive
effect.] To really be useful, and produce significant
distortion, a mass must be very compact and must be rotating very,
very quickly. Atoms with unbalanced nuclei must be used in order to
maintain, through inertial imbalances, a changing
orientation throughout each rotation. Otherwise, the nuclei will
maintain their position and little distortion will occur, much like
water and ice in a glass tend to hold their positions no matter how
one turns the glass. But even with unbalanced nuclei, simply spinning
normal samples of matter at achievable speeds has produced only
minimal effects.
Perhaps a feasible alternative would be to rotate many
atomic nuclei individually at very high speeds. Nuclei are
ultra-dense, nearly like little neutron stars or black holes, but with
protons and a positive charge. Because nuclei rotate fairly stabily
and without friction, it is possible to accelerate their rotation to
their maximum speed and produce very strong Doppler
distortions from their axis. Aligning all the axis of nucleic rotation
in a sample would provide directed distortion waves.
There exists several ways to accomplish this nucleic
spin. Rotation may be initiated primarily by free electron inertial
transference, variable magnetic fields, or secondarily by
gravitational or protonic or valence electron inertial transference
(one nucleus, or it's electrons transfer their momentum to another).
Combinations of these methods might increase overall efficiency of a
design.
Electrically Induced Rotation
Certain nucleic geometries reflect, to a significant
degree, the movements of nearby electrons. The elements that exhibit
such geometries have an odd number of protons and an even number of
neutrons. In such atoms, the protons are not uniformly dispersed
throughout the nucleus.
Instead, one side of the nucleus is slightly more positive than the
other. These elements exhibit a slight natural distortion effect that
may be deduced by observing their atomic radii, which are
significantly smaller than expected due to the repulsive effect
generated by nearby nuclei. The unbalanced element with the most
massive nucleus is Bismuth, element 83. It is the most diamagnetic
(generates an opposite magnetic field to the one that is applied) of
all the elements. Its nucleus has the most amount of matter available
for distorted wave production and also has the strongest inter-nucleic
attractive forces which allow it the highest maximum spin rate of all
the unbalanced nuclei. These factors combine to make Bismuth the
obvious choice for electro-repulsive experiments. A stable element 115
would be better than Bismuth, but recent research shows that that the
half-life is only around 30 seconds. It is possible that
superconductive materials (due to their complete diamagnetism
at cold temperatures) might be superior to Bismuth; however, they
might not due to their molecular structure. The question must be
answered, but no one wants to have to dip their antigravity craft in
liquid nitrogen every 20 minutes or so, anyway.
To spin nuclei with electricity, it may be preferable to
use thin Bismuth films and pass high-voltage DC pulses across them to
speed and align nucleic rotation. High-voltage current has a tendency
to travel on surfaces as far as possible from the interior of the
conductor. Therefore, the current would be most likely to pass over
the tops of the surface Bismuth atoms and less likely to pass through
the valleys between them due to the electrical pressure. The effect on
the individual nuclei can be likened to water falling over a
waterwheel. This
tendency would allow the axis of the Bismuth atoms to align
perpendicular to the current direction and tangential to the film
plane while simultaneously initiating and speeding nucleic
rotation. Distorted waves would be emitted from the nuclei parallel to
the axis. Depending upon amperage and ribbon thickness, these
rotations may be initiated and maintained throughout the entire
thickness with a single reversal of rotational direction in the middle
or the ribbon, or with a very weak current, inertial transference may
induce counter-rotations of the Bismuth atoms that lie beneath the
surface layer. It is not known what effect counter-rotations would
have on efficiency, but I suspect they would be counter-productive.
Therefore, to minimize significant counter-rotation, limiting the
thickness of the Bismuth film would seem to be important. Of course,
simultaneously sending DC pulses in one direction on one side of the
film, and in a counter direction on the other side of the film would
solve counter-rotation problems completely, but this is only possible
using multi-layered materials.
To initiate rotation it might be desirable to provide a
highly conductive layer adjacent to the Bismuth film (Art Bell's
Roswell Debris: http://www.artbell.com/rosreprt.html, and personal
communication with Steve Wingate). With this adaptation, charge still
races across the Bismuth surface speeding and aligning nucleic
rotation. Use of an element with balanced nuclei would be recommended
to reduce the chance of rotational instability and disruptions due to
interactions
between the different layers. Magnesium would be the obvious choice
due to its high conductivity and light weight. Multiple Bismuth and
Magnesium layers might be sandwiched on top of one another for greater
effect. High-voltage pulsed current passed through the Magnesium,
switching back across the Bismuth layers would eliminate
counter-rotations and effect distorted waves from the nuclei towards
the directions perpendicular to the electron flow and tangential to
the sandwich plane. It might not be physically possible to switch back
the current across a single Bismuth layer in this fashion, but it
should certainly be tried. [The extra conductive layer may not be
necessary, as research into Bismuth films and micro-filaments suggests
a natural superconductive tendency that is not present in thicker
samples. I believe that the superconductive effect results from the
alignment of nucleic spins with nuclei acting as electron guides to
reduce eddying and resistance.]
Possibly an experimental compact design would be similar
to this. Around a conductive central core, a Bismuth film ten
centimeters wide, half a kilometer long, and a few microns thick is
wrapped. From the core and between each successive Bismuth layer a
similar dielectric layer is wrapped in a similar fashion to prevent a
charge from taking a shortcut and bypassing a portion of the
half-kilometer length. If the free end of the Bismuth film is
grounded, and a sufficient high-voltage pulsed current is passed from
the core to the ground, distorted waves would be emitted out the top
and bottom of the device. [A possibly more efficient, modified design
using pulses travelling in opposite directions on each side of the
Bismuth film would also be possible.] As stated above, possibly the
single Bismuth film in this design may need to be replaced by a
Bismuth/Magnesium sandwich for more efficient rotation initiation.
However, once rotation is achieved, little energy is needed to
continue rotation and wave distortion - the nuclei act as little
flywheels. An interesting point of this design is its ability to work
at a distance. Distorted waves are emitted in two
approximate beams if the nucleic spin is stable enough. These beams
would neither increase nor decrease over distance, only spread out
according to the stability of the nucleic rotation. The simplest
stable platform based on this design would be an equilateral triangle
with one distortion generator of this type at each corner. Varying the
generators' orientations would provide maneuverability.
Another design that would be useful would be to use the
successive Bismuth-dielectric films or Bismuth-Magnesium films to coat
the outer surface of various shapes to provide repulsion across larger
surfaces. The first shape to consider is the cigar shape. When coated
with successive layers and a sufficient charge is passed through the
"skin" from one end of the cigar to the other, or sequentially back
and forth across the Bismuth layers, distorted waves from each nucleus
are generated towards the directions tangential to the skin and
perpendicular to the plane which contains the nucleus and the cigar's
lengthwise axis. Not only would this configuration provide a nice even
lift, it would naturally align the cigar parallel to the
earth's surface. It would also deflect, to a degree dependent on the
degree of distortion, all objects on an approach path towards it. This
would provide protection from micrometeorites, projectiles, and even
particle beam weapons if the distortion was
strong enough - anything that is affected by gravity can be deflected.
For maneuverability, a compact distortion generator as described above
at each end of the cigar would do the job.
The next logical shape to explore is the traditional
"flying saucer" or disk shape. If coated similarly to the above cigar,
and charged from top to bottom or sequentially back and forth across
the Bismuth layers, distorted waves would be emitted towards the
directions tangential to the skin and perpendicular to the plane which
contains the nucleus and the axis of the disk. If sitting on the
ground, it would repulse laterally - providing zero lift. To move the
nucleic axis from the lateral, the current pulses need to be made to
travel around the axis of the saucer shape instead of taking the
shortest, fastest route between poles. The closer the spiraling of the
electron flow, the closer the repulsive field aligns with the axis
plane and therefore repulses more up and down. This spiraling may be
accomplished with a spirally wound core or more efficiently with a
winding just deep of exterior surface. With this design, only one
compact distortion generator mounted axially is needed to provide
maneuverability. Maneuvering might also be accomplished by varying the
orientation of the spirally wound core.
There are limitations to these designs arising from the
fact that all the distorted waves are directed tangential to the
surface and never reach the interior of the craft. This limits the
acceleration and deceleration to that which a human body could
withstand. Why not put the occupants outside, under a dome on top of
the craft? This way, the repulsion forces generated would, to a large
degree, counter-balance the inertial forces on occupants as the craft
accelerated. Another solution might be to use a distortion skin with a
rippled shape rather
than smooth.
There are many other possible shapes and configurations
to explore using this wave distorting skin and modifications of the
more compact design and combinations of them both.
Magnetically Induced Rotation
It also possible to induce nucleic rotation
magnetically, but as the methods described above would seem to be more
efficient, I have not concentrated heavily on it. My first design idea
was to use a cylinder of Bismuth rotated within a collar of
alternating magnetic poles. As the individual Bismuth atoms pass by a
north pole, they will be turned and will complete a single rotation as
they pass by the south pole. Thus for every two magnetic poles in the
collar, one nucleic spin will be initiated. I would call it a
rotational amplification device. Using a motor operating at 25,000 and
forty permanent or electromagnets in the collar, I would expect
individual nucleic spins at 500,000 rpm as the whole core rotates at
25,000 rpm. The whole thing will look like a sun picture with the
Bismuth core as the sun and forty electromagnet "rays." However, this
design might have a problem with heat evolution which could disrupt
rotational stability. This design is the logical next step for those
who wish to improve on Podkletnev's ideas.
My second idea was to construct a coil around a ferrous
sleeve containing a Bismuth core. Using an AC frequency generator at
the coils resonant frequency and then moving up the coil's harmonics
would be a simpler and much more efficient method of inducing
extremely rapid nucleic rotations in the Bismuth core. With this
design, the speed of achievable rotations is dependent on the harmonic
used and limited only by the highest harmonic used. again, this design
might have problems with heat evolution. Again, a chilled
superconducting core might increase
efficiency.
Using this concept, it is also possible to construct a
craft with a Bismuth shell on the outside and the coil on the inside
around a ferrous rod. Hitting the coil at its resonant frequency and
its harmonics should accomplish the same trick. Varying the position
of the coil would allow for maneuverability. Again, there are many
variations and combinations on this design which need to be explored.
Well, I've never been very good at wrapping things up,
so I will just say "peace" and "God bless."
Contact information:
by Joshua Gulick
June 25, 1999
Joshua Gulick
Email: joshua.gulick@cheerful.com
Website: http://www.freez.com/joshua
ICQ # 42262662