ZetaTalk: Science

ZetaTalk: Elliptical

Note: written during the 2001 sci.astro debates.

Clearly, more than the regular flow of gravity particles from and back into a Sun is at play in planetary orbits, else all

these orbits would be circular. There are countless influences, but these influences can be summarized into their effect, which accounts for an elliptical orbit.

Secondary Gravity Influence

Planets that orbit both binary suns do so in a figure 8, pulling toward the second binary at the

juncture where the planet is positioned between the binaries, but propelled by momentum to

continue its orbital curve while moving toward the second binary. But planets caught between

binary suns, but orbiting a single sun, pull wider toward the second binary in their orbit, creating an

ellipse that leans toward the second binary.

Escape Attempt

Just as two North Poles in a magnetic object will avoid each other, pushing the lighter object to

align with the heavier object, other repulsion forces can push an orbiting planet closer to its Sun

than the flow of gravity particles would ordinarily allow, putting the planet in a squeeze between

these repulsion forces. The result is a rush to leave the squeeze, such that the planet accelerates at

this point in its orbit, giving it momentum as it stretches into the long part of the ellipse.

Dithering

Planets positioned such that they have several attractions can be slowed in their orbit due to

dithering. Such dither points are not even in the orbit, so create a speeding up as the planet

approaches the dither point, and a slowing down as it leaves this point. Rushing to an attraction

causes the orbit to draw long at that point, a factor of momentum on the orbiting planet, which is an

influence toward an elliptical orbit. Where no apparent gravitational giant exists to explain the

elliptical orbit, particle flows other than gravity are the dominant influence on the shape of the orbit.

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ZetaTalk: Slowing Probes

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ZetaTalk: Slowing Probes

Note: written during the 2001 sci.astro debates.

An unknown force seeming to pull on a pair of distant space probes has left astronomers with a weighty mystery,

one that appears to defy the conventional laws of physics. The Pioneer 10 and Pioneer 11 spacecraft, which for

decades have steadily traveled in opposite directions in the solar system, have covered significantly less space then

they should have.

CNN

Why do the probes slow? It is not gravity, the Sun pulling these probes back, but particle flows that mankind is

currently unaware of. Why do the planets in the solar system all line up into the ecliptic plane? This phenomena occurs

in the rings around Saturn also, and in the oceans of Earth which are fatter at the equator than at the poles. Visible

matter, the planets and rings and oceans, that mankind can see, are slung faster from the waist of a rotating sun or

planet than at the poles, a matter of momentum But it is not the sling that keeps them at the waist, as a sling alone

would not keep them nicely in place, a ring around the waist. There is a return of some type, with the return coming

back into the rotating sun or planet at the poles, and then flowing in the direction of the waist, to fill the gap caused by

the sling. This is not caused by the flow of gravity particles, as the flow of gravity particles is even. Does an object

weigh more at the poles than at the equator? Nor is this the flow of magnetic particles, as the rings around Saturn and

the planets in the ecliptic assume their position regardless of magnetic properties.

The solar wind is not visible to man, yet its effect on comet tails is quite visible. Likewise, the flow of these particles,

unknown to mankind, which force the planets into the ecliptic plane, can be inferred from the fact that the ecliptic

exists, alone. The probes, propelled beyond the grip of the Sun’s gravitational field to where their momentum can

counteract this draw, were expected to float along at a predictable rate, yet are doing so more slowly. The answer lies

in the wash back of the particle flows that keep the planets bobbling in the ecliptic plane and the rings of Saturn so

neatly in a thin line. Just as the fatter oceans around Earth’s equator flow toward the poles, thence wrapping around in

deep ocean current back toward the equator, this particle flow is not even in the pressure it exerts. There is pressure

from the side as well as back toward the rotating sun or planet that is the gravitational giant holding the bobbling

matter in its grip. The closer the bobbling matter is to the equator of a rotating object, the more pressure there is from

the side, pushing the matter into the ring or ecliptic plane.

The probes were in part sent out to explore the planets in the solar system, and were directed by their jets or a

gravitational sling around the planets being visited during their voyage. Thus, the force of gravity from the Sun alone

was not the single force influencing the probes until they floated to where they are today. They now, presumably, have

only their momentum and the gravity pull from the Sun as factors in their pace. Add to this the factor of a returning

particle flow, pushing outward at the ecliptic but immediately upon leaving the ecliptic plane flowing back toward the

Sun. As the particle flow leaves the ecliptic, it is flowing toward the side, away from the ecliptic, but in the backward trip, it is buffeting from the other side, as the currents of this flow become circular around the ecliptic close in, as well

as circular in broad circles that extent to the poles of the Sun. This buffeting from the side affects the rate of escape in

the probes, as they are making side trips, this way and that, however infinitesimal, and this likewise takes time. How