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White Holes
White holes are similar to black holes except
white holes are ejecting matter verses black holes are absorbing matter.
In 1916, Karl Schwarzschild derived the first
model of a black hole using Einstein's theory of
general theory of
relativity. Nothing, not even a particle moving at the speed of light,
can escape the gravitational pull of a black hole. The
existence of white holes is implied by
a negative square root solution to the Schwarzchild metric for space-time-matter
continuum.. It is important to remember that black and white holes
can be composed from matter or antimatter.
A worm hole, which joins white holes, is
known as the
Einstein-Rosen bridge and is one of the most fascinating concepts in
theoretical physics. In 1962, John
Wheeler discovered the Einstein-Rosen bridge space-time-matter metric. Theoretically, a worm hole could
be stabilized to allow a safe equilibrium between matter and antimatter white holes.
To stabilize the worm hole, the throat of the singularity contains matter and antimatter white holes, which are
spherical in nature. The antimatter has a negative mass and exerts a positive
surface pressure.
Scientists have questioned the existence of black holes for decades.
On May 27, 2004, Edward Churchwell, a University of Wisconsin-Madison astronomer, announced their findings using NASA's
Spitzer Space Telescope that the Milky Way Galaxy was
churned out
hundreds of new stars. The
black holes in the
center of galaxies are composed of condensed matter and antimatter. The
black holes have the mass of a billions of suns. The
Einstein-Rosen Bridge keeps the matter and antimatter black holes separated.
The oscillations between the black holes at
opposite ends of the wormhole force the black holes to become
white holes that eject matter and antimatter in
opposite directions forming the spiral arms of stars within the galactic disk. The antimatter negative mass ensures the throat of the worm hole lies
outside the protected region and the positive surface pressure prevents the throat of the worm hole from
completely collapsing. The matter and antimatter properties are not arbitrary or purely theoretical for producing a
stable worm hole. Einstein's equations specify what the energy-momentum content of matter must be in an area to produce the needed geometry. Matter and antimatter white holes can stabilize
a worm hole.
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