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Black holes are rips in space-time where gravity is so strong that even light cannot escape them, making them appear to be large spheres. In reality, the surface of the sphere is just the point at which light cannot escape, so it appears to be black. This surface of the black hole is called the event horizon.

The center of a black hole is an infinitely small and infinitely dense point within spacetime, usually called a singularity. Increasing the mass of the singularity effects the curvature of spacetime and causes the black hole's event horizon to grow in size.

A non-moving black hole can be described by only it's mass, electric charge, and angular momentum. In other words, two black holes with the same mass, electric charge, and angular momentum would be physically indistinguishable from each other besides their position.

Formation[]

Black holes are formed when a star burns out and has enough gravity, in which it will then collapse in onto itself, usually creating a supernova. The density inside the center of the star while it collapses becomes enough that a singularity forms, and so a black hole is created. Black holes have also been created naturally by advanced civilizations outside of our Universe by squishing huge amounts of matter in one spot.

Evaporation[]

Main article: Hawking radiation

In 1974, Hawking predicted that black holes are not entirely black but emit small amounts of thermal radiation at a temperature ℏc3/(8πGMkB); this effect has become known as Hawking radiation. By applying quantum field theory to a static black hole background, he determined that a black hole should emit particles that display a perfect black body spectrum. Since Hawking's publication, many others have verified the result through various approaches. If Hawking's theory of black hole radiation is correct, then black holes are expected to shrink and evaporate over time as they lose mass by the emission of photons and other particles. The temperature of this thermal spectrum (Hawking temperature) is proportional to the surface gravity of the black hole, which, for a Schwarzschild black hole, is inversely proportional to the mass. Hence, large black holes emit less radiation than small black holes.

A stellar black hole of 1 M has a Hawking temperature of 62 nanokelvins. This is far less than the 2.7 K temperature of the cosmic microwave background radiation. Stellar-mass or larger black holes receive more mass from the cosmic microwave background than they emit through Hawking radiation and thus will grow instead of shrinking. To have a Hawking temperature larger than 2.7 K (and be able to evaporate), a black hole would need a mass less than the Moon. Such a black hole would have a diameter of less than a tenth of a millimeter.

If a black hole is very small, the radiation effects are expected to become very strong. A black hole with the mass of a car would have a diameter of about 10−24 m and take a nanosecond to evaporate, during which time it would briefly have a luminosity of more than 200 times that of the Sun. Lower-mass black holes are expected to evaporate even faster; for example, a black hole of mass 1 TeV/c2 would take less than 10−88 seconds to evaporate completely. For such a small black hole, quantum gravity effects are expected to play an important role and could hypothetically make such a small black hole stable, although current developments in quantum gravity do not indicate this is the case.

If black holes evaporate via Hawking radiation, a solar mass black hole will evaporate (beginning once the temperature of the cosmic microwave background drops below that of the black hole) over a period of 1064 years. A supermassive black hole with a mass of 1011 M will evaporate in around 2×10100 years.

Guesses about the maximal degeneracy area[]

General relativity and its singularity and ringularity fail to describe the physical degeneracy torus of a rotating black hole, because they describe no spacetime mechanism. Quantum field theory can describe maximal degeneracy (of spacetime itself) as a pretransitional phase (pre-Big-Bang state), and that will happen in the future.

Almost all professors erroneously never mention (when speaking about black holes) that quantum tunneling can happen when enough energy is compressing a particle and when the boundaries confining it aren't strong and thick enough to confine it. Replace the word particle with maximal degeneracy pressure. Natural rotating black holes have an intricate interior behind their event horizon. Their maximal degeneracy pressure area wants to tunnel out, and quantum tunneling is restricted by gravity but not prohibited; also gravity doesn't have the same value everywhere; relative weaker gravity curvature regions exist behind the event horizon and there the degeneracy loop tunneling reabsorption mechanism can exist (we have to use the schematic of the rotating black hole, and add tunneling loops surrounding the maximal degeneracy region). The result is a permanent flow of looping tunneling surrounding the maximal degeneracy pressure area. This view can explain why miniscule black holes immediately evaporate = their event horizon is too small to have a degeneracy reabsorption mechanism behind the event horizon. Also this view can explain why quasars emit huge amounts of radiation; quasars consume mass–energy too fast, and their event horizon cannot grow big enough in time due to inertia, thus a part of the degeneracy reabsorption mechanism gets exposed outside the event horizon and most of that mass–energy escapes. All these things are guesses, but what is the alternative explanation? We should start explaining these mechanisms somehow. We don't have the quantum field theory definition of maximal degeneracy pressure. Not all regions behind the event horizon are maximally degenerate. Maximal degeneracy pressure is maximally compressed spacetime. No specific particles are able to get expressed there, but the overall maximal degeneracy region is one particle as a whole. If these ideas are wrong what is the alternative? Organize multidisciplinary groups of scientists to find better descriptions.


Star Classes
Main Sequence:

Y · T · L · M · K · G · F · A · B · O · Ξ · ΔK · ΔM · ΔG · ΔT · ΔP · ΔE · ΔZ · ΔY · ΔR · Q · ω

  • Dwarves:

D · Θ

  • Holes:

Ω

  • Other:

? · σ · þ · φ

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