planet, find a down-draft and updraft of gravity particles in balance, what humans might term in their ignorance a zero
gravity field, weightlessness. At this point the updrafts are still tearing through, but at a slower rate, so that a
mechanical push upward is involved, and the down-drafts are more thinly dispersed over the surface as they work their
way through the density of these objects in space. Large bodies, exuding their own updrafts of gravity particles, create
a situation where their updrafts and the updrafts from another sun or planet bump against each other, creating a buffer
and preventing the gravity masses from touching or even approaching each other except at great distances.
Within black holes, the down-draft
http://www.zetatalk2.com/science/s96.htm[2/5/2012 11:53:56 AM]
ZetaTalk: Galaxies
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The Repulsion Force is what keeps suns apart, at the distance they are, or at least is a factor in this. The reach of the
force of gravity is immense, as with the distance that light particles travel, but like light particles gravity particles on
the move can be deflected. Light particles reaching man from across the galaxies has moved in essentially a straight
path, unless being deflected or absorbed by something in its path. What is the drama that occurs when
gravity giants are in a vicinity, and why is it that binary suns are so common?
Gravity particles with a single gravitational giant in the vicinity float into the giant and spurt out, without
conflict. At the end of a spurt, their desire to clump with their kind causes them to return to the nearest clump.
This could be equated to light escaping from a Black Hole, where it is on the move but not leaving, rather
returning. The fact that other gravity particles in the vicinity are returning is no small part in this, as those in the
flow are attracted to one another also, so the particles at the end of a spurt find they also are
gravitational giant as a result of trying to move to gravity particles nearby.
When there are two gravitational giants of equal size, as in binary suns, the drama is joined by a dither point
between the two. Gravity particles at the end of a spurt, or slowing in their exit due to reduced pressure as
dissipation occurs, find a mixture of streams going back to
are intermittent, so at one time the dither leans more toward one giant where a return flow is ongoing, but at
another time the return stream to the other giant is stronger, and a particular gravity particle switches to flow into
and out of the other sun. Where the suns are matched in size, they stay apart where the Repulsion Force keeps
them, to the extent that their dance is dominated by gravity.
Gravity particles streaming in an outburst from a giant but
can move outward to a great distance. This is dependent upon the force with which they are expelled from the
giant, giving them great momentum. At the same time, the single drama of each gravity giant continues, and any
binary dance that has developed between balanced suns continues, so the particles escaping the area are those not
caught in other dramas. Gravity attraction is a
Bang, and bringing this together again during a collapse, ultimately into another immense Black Hole. Other
subatomic particles are more significant in the dance between galaxies, however. Gravity dances tend to be a
local affair.
http://www.zetatalk2.com/science/s117.htm[2/5/2012 11:53:56 AM]
ZetaTalk: Particle Flow
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Magnetic particles flow from the nucleus and back into the nucleus on the other side of the atom. Where the iron atom
is among others in a fluid state, such as liquid metal when heated, the flow moves from one atom’s outlet point to the
intake point of another atom nearby, thus magnetized iron. Humans have learned to magnify and set the direction in
this liquid iron by setting a strong magnet alongside, creating yet another magnet in the process. Some humans are
confused by our magnetism cycle description of 3 groups of 3 in a cycle of 10, or 4 groups of 3 in a cycle of 12. A
cycle is a completed electron or other subatomic particle pattern around the nucleus of an atom. Equate the subatomic
magnetic particles and their pattern, for simplicities sake, to sub-way trains leaving the central station to go out into
the suburbs and then returning. Normally the train schedules are regular, continuous, but in some cities they become
infrequent during the middle of the day or middle of the night, when there are expected to be few travelers. There may
even be breaks in the pattern so that shift turnover can occur, or maintenance. Now, equate the flow of magnetic
particles from the nucleus to the steady press of passengers, and assume a steady flow arriving at the central station.
