ZetaTalk: Science

moons of

Planet X, which trail it like a string of pearls out in space, have no such little jets, so nature, not man, rules, and the

full result of a spin out in space can be observed. Why do the moons trail, and spin in a slow whirlwind behind Planet

X, rather than orbit the planet?

Moons in orbit around planets in a relatively circular orbit around a sun have more than their planet affecting their

behavior. They are of a mass that prevents their plummeting to the planet, as they are evoking the gravitational

repulsion force between themselves and their planet. They are moving, not stationary, not because of the attraction to

the planet, which is at a standstill, but because of attractions to other elements in the solar system. Like a liquid core of

a rotating body, they are moving toward what attracts them, overshooting the point where they are closest to the

attractant, moving around to the far point because of momentum, and proceeding to approach the attractant again.

Where there are a number of moons orbiting a planet, they position themselves like the planets around a sun, at a

comfortable distance from each other to avoid collision, as the repulsion force is in operation between the moons,

which are of relatively equal size, too.

Where it would seems that an orbit, in an orbital plane, around a sun or an planet is the natural outcome, this is

disrupted during the swift passage that Planet X makes past one of its foci, the sun or its dead twin some 18.74 Sun-

Pluto lengths away. Planet X moves away from its moons, pulling forward with increasing speed, at the same time that

it is passing one of its suns and any planets that are orbiting that sun. The moons have conflicting dictates.

Their primary allegiance is to Planet X, due to the flow of gravity particles which force it toward Planet X,

which they are thus bound to. They are thus trying to catch up to Planet X, even when Planet X leaves them

behind.

The secondary influence over the moons is momentum, which continues to cause them to overshoot a reach for

an attractant in the vicinity, to return to the far point of their spin whence they start back again toward the

attractant. Thus, they continue the rotation or orbit pattern, even when not in a tight orbit around their planet.

The third influence, which comes to interfere with a return to a tight orbit around Planet X, is each other. Moons

around a planet that does not move rapidly away from its moons have established their positions in part because

the moons arrive one at a time! Each new arrival finds an orbit plane taken, and assumes another or displaces the

first, but the factors that dictate position are more static than moons traveling behind a rapidly moving planet. In

essence, the positions are determined because one moon says 'I am larger than you, and I wish this position of

closeness to the planet, so you have to move.'

Moons that have arrived in a whirlwind behind a rapidly traveling planet have a new dictate to deal with, in that they

find other moons directly in the path they wish to take toward their gravitational giant, in this case Planet X. They are trying to catch the planet, while caught in momentum that their circular chase toward other attractants in the vicinity

has created, but during their approach to their planet they find other moons in the way and this causes a fourth dictate, a bump away from their traveling planet.

http://www.zetatalk2.com/science/s123.htm[2/5/2012 11:54:35 AM]

ZetaTalk: Swirling Moons

In moons around a static or slowly orbiting planet, the moons have opportunity to snug closer to the planet when

competing moons are on the opposite side of the planet. When such moons encounter each other, having

assumed the same orbital plane, the smaller gets bumped out of the path of the larger, either below the path of

the larger moon, or most often farther away from the planet.

In moons that have found themselves trailing their planet, this bumping takes the form of increased circular

motion. The moons are already moving in a circular path, caused as we have mentioned by attractants in the

vicinity which they are chasing toward and overshooting while still bound to their gravitational master. The

swirling is increased as each time a larger moon attempts to approach its planet, it encounters other moons

directly in its path which have nowhere to go but round and round, so they go faster. Collisions are avoided by

more rapid motion, and none of the moons can place themselves on the opposite side of the planet. They are all

stuck in a corridor behind the planet, not able to leave, not able to pass each other, and not able to catch the

planet to reinstated a circular orbit around it.

Why would such a moon pattern perpetuate itself? Does Planet X not come to a virtual stop at the mid-point between

its two foci? Having established a swirl behind the planet, the moons have two factors preventing a return to the

normal orbital pattern of moons around a planet. First, their swirl perpetuates itself. The speed is dictated not only by

the normal rotation around a gravitational master that attractants in the vicinity would create, it is dictated by the need

to move away from the other moons in the swirl. Second, the larger moons in the cluster are perpetually trying to reach

a closer proximity to their planet, the point where the repulsion force between the moon and its planet creates a