In the AV model, there are no electrostatic charges.
To understand this, let's review the Hydrogen atom.
At its center, incoming opposing lines of Gravity
convert to expanding spheres of Space. Unopposed
lines of incoming Gravity convert to Linear motion.
As a carryover from the compression period, some
of the Gravity converts to Ray. This Ray goes to the
survace and converts to Space. This conversion
creates a disturbance on the surface of the Shell.
As Ray rotates, this disturbance orbits the center
of the Shell. A viewer on the outside sees this
disturbance and calls it an electron. It is given a
negative value because the viewer is on the other
side of Ray. Likewise, the neutron in the center is
given a positive value because the viewer is on the
same side as Ray.
In the AV model, everything is now converting to
Space. This is a slow process because Space is
also converting to Gravity, and some Gravity is still
converting to Space. As the number of mass
centers decrease, the amount of new Space being
created diminishes. In general, everything attempts
to maintain a steady state.
Let's now look at an atom with four neutrons in orbit
about its center. In its stable state, Ray goes to the
surface and converts to Space.
Now add energy to this system. As Ray enters, it
converts to Spin and the neutrons orbit faster. To
return to its stable state, these neutrons slowly
convert their extra Spin to Rays. These Rays go to
the surface and convert to Space. These Rays also
create a disturbance on the surface of the Shell.
Again, the observer is on the opposite side of these
Rays and the disturbances appear negative. One
says the Shell has a negative electrostatic charge.
Now consider the case where the four neutrons
are at the center of the atom or normal Shell. In this
case, Rays enter the Shell, but they still create
local disturbances on the surface of the Shell.
As more Rays enter, the neutrons begin to orbit
the center and return to their normal state. Before
this, however, the surface appears to have a
positive electrostatic charge.
It is said that opposite charges attract each other
while like charges repel each other. To test this
repel belief, one needs to remove one of the gold
leaves fron an electroscope and touch it with a
charged rod. The leaf should not move.
http://en.wikipedia.org/wiki/Electroscope
Sunday, May 15, 2011
Friday, May 13, 2011
ANTIMATER
What is antimatter?
We know that matter comprises what physicists
call particles: electrons, protons and neutrons.
If one sticks an 'anti-' in front of each of these
particles, then one has antimatter. But, does
antimater exist?
In the AV model, our physical universe is a
school, and its purpose is to teach us how
to reason logically. This school cycles from
one Big Bang to the next. So, does it make
sense to include antimatter which will hasten
the cyclic process? It is like building a large
school and setting one part on fire!
In the AV model, there is no electron per se.
However, there are the folloing fields which
no scientist talks about: Space, Kone, Ray,
subNeutron, plus Gravity is going in the wrong
direction. So, since pieces are missing, antimatter
may be just an idea to explain the unexplainable.
For example, assume a set of subNeutrons in a
small verticle circle with a Hydrogen atom on each
side. Gravity pushes the Neutrons in the two atoms
toward the circle's center. Gravity also pushes the
two centers of the atoms toward the circle's center.
While this is happening, the fields of the two atoms
or normal shells keep spinning between the
Neutrons and subNeutrons. Assume they are both
spinning clockwise. This means they are spinning
in opposite directions at the circle's center. If the
pressure is too great and the fields cannot spin,
then they will unSpin and convert the two normal
Shells to Space and other fields.
However, since the scientist is not looking for
a subNeutron, the scientist will not see it, and
antimatter becomes a good guess.
We know that matter comprises what physicists
call particles: electrons, protons and neutrons.
If one sticks an 'anti-' in front of each of these
particles, then one has antimatter. But, does
antimater exist?
In the AV model, our physical universe is a
school, and its purpose is to teach us how
to reason logically. This school cycles from
one Big Bang to the next. So, does it make
sense to include antimatter which will hasten
the cyclic process? It is like building a large
school and setting one part on fire!
In the AV model, there is no electron per se.
However, there are the folloing fields which
no scientist talks about: Space, Kone, Ray,
subNeutron, plus Gravity is going in the wrong
direction. So, since pieces are missing, antimatter
may be just an idea to explain the unexplainable.
For example, assume a set of subNeutrons in a
small verticle circle with a Hydrogen atom on each
side. Gravity pushes the Neutrons in the two atoms
toward the circle's center. Gravity also pushes the
two centers of the atoms toward the circle's center.
While this is happening, the fields of the two atoms
or normal shells keep spinning between the
Neutrons and subNeutrons. Assume they are both
spinning clockwise. This means they are spinning
in opposite directions at the circle's center. If the
pressure is too great and the fields cannot spin,
then they will unSpin and convert the two normal
Shells to Space and other fields.
However, since the scientist is not looking for
a subNeutron, the scientist will not see it, and
antimatter becomes a good guess.
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