Other Moons and the Sun
Whereas our own moon orbits the earth, and the Earth orbits the Sun, Pluto and its moon both circle each other as well as the Sun. These and many other irregular orbits are not explained by gravity. However, as in Descartes’ model there is a vortex within the dense fluid of dark matter. A vortex is a whirlpool as seen in a basin, when the plug is pulled. In the Northern hemisphere this water vortex is seen to be clockwise, and in the southern hemisphere it is anticlockwise. This amazing effect is seen only a foot or two from the equatorial line. This phenomenon is called the “Colleolis Effect”, caused by the rotation of the dark matter around the Earth. If the dark matter were not there, there would be no vortex. In space though, there are no attractive forces between the sun and the planets whatsoever. Some moons are seen to orbit far too close to their planets for that orbit to be sustainable within any force of gravity. Since gravity does not exist, and the dark matter holds the moon in its orbit, the moon can remain indefinitely at any distance from a planet. Likewise, binary (paired) stars rotate closely around each other and should have come together like a magnet years ago, had gravity ever have existed. The sun also has a vortex. All the planets and comets orbit around it in the vortex of dark matter, in the same direction.
The Sun’s corona is formed of the lightest particles, and these are thrown thousands of miles into space, from within a body of apparently massive gravity. Gravity does not exist, so the particles can readily escape and fall back slowly in the pressure gradient of the dark matter.
If gravity existed in the mass of a planet, then the light molecules of gas in that planet’s atmosphere would either be attracted onto the surface, or to the sun. Gas could not remain in the atmosphere. Instead the dark matter is suffused throughout the atmosphere, causing a pressure gradient, transmitting the light, radio and microwaves. It may be that individual or certain types of dark matter particles, mainly or solely transmit different types of radiation, and magnetism. It is likely that neutrinos for instance are as densely populous as any other particles, but that they do not normally transmit light. The detectors that have been constructed for neutrinos, are simply seeing an occasional light wave after some sort of insult to their structure.[i]
[i] Nature, volume 411,
“On the trail of the neutrino”. “Huge arrays of detectors
now have these ghostly particles in their sights - but will they lead
physicists to rethink the standard model?
In
the sub-atomic Zoo, few particles are as elusive as the neutrino. The universe
is awash with them, but they slide through most forms of matter with ease.
Billions have passed through your body since you started reading this article.
By one estimate the average neutrino could travel for 1000 light years through
solid matter before being stopped. This reluctance to interact with matter
makes neutrinos difficult to detect. But, almost half-a-century after they were
first spotted, neutrinos have become the focus of
intense study. Exciting results from existing detectors, together with plans
for new detector projects, promise to make this a busy decade for the neutrino
hunters”. ……
“The only practical way to snag a neutrino hinges on the weak nuclear force and on the interaction between neutrinos and protons, neutrinos or electrons it governs. Physicists maximise their chances of observing these rare interactions by monitoring huge numbers of potential neutrino targets. Large tanks of water are a common choice – water is plentiful, cheap and being transparent, it allows physicists to observe any interactions that occur deep in the tank. The tanks are deep in the ground so that other particles are screened out by the overlying rock. There are several types of interaction to look for. The simplest is elastic scattering - high-speed collisions between electrons in water molecules and incoming neutrinos. The collision leaves the electrons travelling faster than the speed of light through water. As a result the electrons emit dim blue flashes of light known as Cerenkov radiation - the optical equivalent of the sonic boom created by supersonic aircraft”.