Introduction
Modern science considers our Universe to be vast and possibly infinite. However, an alternative hypothesis suggests that our Universe could be the internal part of a giant black hole or a black star. According to this model, the internal pressure created by the gravitational collapse of the black star may be responsible for the stability of atoms and the physical laws we observe. Furthermore, the expansion of the Universe can be explained by the fact that the black star continues to absorb matter, transforming it into dark matter.
Physical Model
To test this hypothesis, we can calculate the Schwarzschild radius for a black hole with a mass equivalent to that of the observable Universe. The Schwarzschild radius is determined by the formula:
where:
- m³/kg·s² — gravitational constant,
- kg — approximate mass of the observable Universe,
- m/s — speed of light.
Calculation of the Schwarzschild Radius
Substituting the values into the formula:
Calculations yield:
This radius is approximately 23 billion light-years, which correlates with the size of the observable Universe.
Calculation of the Black Star's Volume
The volume of such a sphere can be determined using the formula:
Substituting the values:
Influence of Dark Matter on Atoms
One of the key ideas of this hypothesis is that the pressure of dark matter is the primary factor ensuring the stability of atoms. Dark matter fills all space and creates an invisible pressure that holds atoms together, preventing them from disintegrating. This explains why, even at high temperatures, atoms retain their structure and molecular bonds remain stable.
Dark Matter as the Driver of Gravity
Dark matter may not simply be a passive medium but an active force that determines gravitational motion in stars. It seeks to fill any voids that arise in space and moves at the speed of light. This could explain the phenomenon of gravitational waves and the stability of stellar systems.
The Role of Dark Matter in Nuclear Explosions
Nuclear explosions are so powerful because their initiation creates microscopic regions where space is temporarily freed from matter, creating conditions for dark matter to instantly fill these voids. Since dark matter moves at the speed of light, this results in a colossal release of energy, which accounts for the immense power of such explosions.
Conclusion
The obtained calculations show that the radius and volume of such a black star align with modern estimates of the size of our Universe. This supports the hypothesis that our Universe may be the inner part of a giant black star that continuously absorbs matter, contributing to the expansion of the Universe and the transformation of ordinary matter into dark matter. Additionally, dark matter plays a crucial role in stabilizing atoms, defining gravitational processes in stars, and influencing the power of nuclear explosions.
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