All of this is predicated on the assumption that gravity is a mono-pole force, drawing matter in towards the center of large bodies. The larger the bodies, the greater the pressure is at the core.
However, the electrical model of the universe has gravity as a dipole force, and most dipole models will predict a cavity at the center of large bodies. The point of maximum pressure is not at the geometrical center of bodies, but in the outer layers.
In an electrical universe, large bodies do not necessarily have a denser composition than smaller bodies made of the same material. There is no central point where all matter is drawn, so there cannot be a super-dense core. The outer layers where the highest density is found is spread out over a large surface.
Without a central point towards which a so called gravitational collapse can focus, black holes and neutron stars cannot form, and there can be no super-dense crystal at the center of our planet.
Recent measurements of Jupiter seems to confirm this conclusion in that Jupiter's core appears to be less dense than its outer layers. Also, a paper presented by Jan Lamprecht in 2003 shows how seismic data related to our planet is easier to interpret using a hollow Earth model than a solid Earth model.
Evidence is adding up in support of the electric universe model in which planets, stars and moons are likely to be hollow rather than solid to the core.
Cross-section of a hollow planet |
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