link to Home Page

Planet X: Moon SWIRL


I’ve been informed that snickering has taken place about the Zeta
statement that the moons of Planet X travel behind it in a slow swirl. 
Below, further explanation.  Perhaps those snickering would like to have
a debate on the issues, such as how such bodies WOULD act in space,
etc.  
 
    Where spin on the surface of a planet is dictated by the 
    moving core of the planet, pulling or pushing on an 
    object free to move on the surface, spin in space is 
    dictated by whatever the spinning object is bound to.  
    This is not explored by man, who strives to move 
    directly in space and treats any spin in an object 
    under their control as a problem to be corrected 
    promptly, as in "the probe has developed a spin and 
    is threatening to spin out of control".  The reasons for
    the spin having developed in the first place is treated 
    as an irrelevancy, and the only issue whether or not 
    the probe is under control. The spin is suppressed by 
    the little jets that allow man to control his probes 
    when their trajectory needs to be corrected, and this 
    thus allows mankind to feel smug about his knowledge 
    of how things work.  The 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.  
     - 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 stalemate.
    Being the larger moons, they push smaller moons away 
    from their path, but this pushing action, in space, has the 
    effect of causing them BOTH to move, thus not only 
    increasing and perpetuating their swirling motion, but 
    also pushing the larger moon AWAY from the planet it 
    seeks to come closer to.

    Thus, the moons of Planet X, having assumed a swirl
    that perpetuates itself, remain in a dance BEHIND 
    Planet X even during its dither point between its two foci.
    Planet X moves, however slowly, at its dither point, so 
    the swirl is always positioned between Planet X and the 
    foci it is leaving.  This swirl, unique to man in any 
    comets or planets it observes, is what caused the 
    ancients to call the passing monster, red in the sky
    because of its illuminated red dust cloud, a dragon, 
    lashing its tail, the swirl of moons.  
        ZetaTalk™