THE
POLAR SHEAF
Eterons have electric characteristics. They
are made up of smaller particles (sub-eterons) that are charges of both
polarities. If such charges are equally scattered it results a neutral eteron.
If not, the eteron has an axis along which there is an electric gradient; that
is to say, one polarity is in majority at one side and the other polarity at
the opposed side. Then a dipole field is generated by the eteron that is in
“dipole-state”. If such eterons are linked by theirs opposed pole-ends they
make a chain that we call as a “polar thread”. Every polar thread has its
dipole orientation: positive at one end and negative at the other end.
An adjacent couple of polar threads with
equal orientation, if still, they repel each other, but they always begin to
move: both in opposed senses. Then they attract between them strongly. So we
have two polar threads moving attached laterally like if they were one thread.
This movement is the “opposed flow”. Such couple of polar threads is a “polar
sheaf”. A bundle of parallel polar sheaves attract among them generating a
“polar sheaf field” (PSF). The lateral attraction generates a force field that
we know as “magnetic field” whose force-vector is perpendicular to the sheaves.
Two adjacent polar sheaves of opposed orientation repel between them. Equal
oriented polar sheaves join together to form a dense field while opposed
orientation makes the dispersion of shaves.
A moving charged particle generates a PSF
where:
One: the orientation of dipoles is in the
moving direction of the particle, that is to say, a moving electron (negative)
makes to point negative ends of the thread’s eterons towards its own moving
direction.
Two: opposed flow of threads creates the
polarization of space. Half of the threads move in the same sense than the
electron with negative ends in the moving direction and the other half flows in
the opposed sense with positive ends ahead. Actually, threads form polar
sheaves of the same orientation. Both threads of a given polar sheaf move in
opposed senses. Both flows (one positive and the other negative) are made up of
eterons in dipole state. The first flow is the “negative space” and the second
(opposed) flow is the “positive space”. As both flows have equal amount of
eterons, the resultant neutral eteron flow is null. Both “polarized spaces” are
in the same geometrical space.
Three: the intensity of the PSF decreases by
the inverse-square of the distance to the moving particle; it increases
lineally with the speed of such particle, expanding laterally and increasing
its total energy by the square.
Four: a PSF generated by a particle tends to
move all the polarized particles inside the field in the same sense than its
own polarity and in the opposed sense to the particles of opposed
polarity.
Five: if the intensity of a PSF reaches a
given value it is able to remove polarized sub-eterons from the eterons and
generate eter-ions.
Then it is possible to generate (by electric
currents) a PSF of high intensity that, at its time, generates a current of eter-ions:
a “subelectric current”.
Let us consider that the space we know is
the surface of a hyper-sphere (see glossary). If in the main space an eteron is
ionized, then the (supposedly positive) cronon-flow (perpendicular to the main
space) pushes positive eter-ions to the upper parallel space and pulls negative
eter-ions to the lower parallel space. In both parallel spaces there are no
eterons but only sub-eterons. Every movement in the main space full of eterons
is limited by the speed of light. In both parallel spaces that speed-limit is
many million times higher due to a much smaller “t” interval. So eter-ions move
at that super-speed. Moreover, when a pair of eter-ions is generated both
(positive and negative ones) move to one of both parallel spaces disappearing
from the main space; then one (or two) neutral eteron(s) disappears leaving a
hole. That hole is filled up at super-speed by the surrounding eterons. But
those disappeared eterons must return to the main space once recovered theirs
neutral condition. If they return at a given distance to the disappearing place
they needs place and they must push aside eterons. Then those pushed eterons
run to fill the mentioned disappearing-hole. On the other hand, ionizing of one
eteron to positive is only possible if we ionize another eteron to negative. Repeating
the concept, it happens by pairs. Both will move to opposed parallel spaces. So
managing properly some electric fields it is possible to put them together
again at a given place. Then they attract among them perpendicular to the main
space where they meet regenerating two neutral eterons that become part of the
amount that fills the disappearing hole. By this way it is possible to create
an “eter-river” or a “neutral eter-flow” or simply “eter flow”. The ionizing
energy is very high but it is recovered at the regenerating zone. So, the
generating of an eter-river demands very low energy, if eterons are not
compressed during the process. Moreover, the eter-river is of continuous
flowing.
Observe that a moving particle also moves
neutral eterons from its front to its back by the intron. But there are two big
differences. One, eterons are compressed to energy states proportional to the
particle’s internal energy (the particle grows in mass proportionally to its
internal energy). Two: it happens by quantum rules generating waves so as to
have a pulsing eter-density.
And just here we have reached one of the
most important goals: to create an eter-flow inside which a big mass can be
moved WITHOUT kinetic energy.
So, at this stage we can begin to describe
three important devices without a mystery veil.
One: the graviton turbine. It is a wheel. It
has horizontal axis. Dividing it by a vertical plane that contains its axis, one
half weighs nothing and the other half weighs the double, generating useful
torque, able to be clutched to a dynamo.
Two: the intron turbine. It will be
described later; it is 20 or 30 times more efficient than the graviton turbine.
Three: propulsion. Eliminating inertia, it
is possible to reach (and pass) the speed of light by electric devices fed by
current generating sets.