What happens to all black holes?

  What happens to all black holes?

 

Are gravity waves the same as Hawking's radiation? 

How can photons escape from a black hole? The fact is that black holes transform all radiation that drops in it into gravitational radiation. Gravitational waves or gravitational radiation is one form of wave movement. If there is a suitable object. That can resonate with the right frequency and wavelength, it's possible to transform any fundamental interaction into another. 

The reason for that is this. All four fundamental forces or fundamental interactions have wave movement and particle forms. 

Chancing the wavelength of those wavelengths that bosons the transportation particles send turns the fundamental interaction into another. So changing the fundamental interaction into another like electromagnetism to weak nuclear interaction happens by changing the wavelength of those interactions. 

Black holes are sending gravity waves, and gravity is one form of radiation. When Stephen Hawking made his famous idea of Hawking's radiation or radiation that could escape from the black hole. 

The gravitational wave's existence was purely hypothetical. LIGO sensor found gravitational radiation in 2015. And Hawking died in 2018. There is the possibility that Hawking didn't have the will or ability to comment on the gravity waves. Gravity waves are causing the idea that maybe Hawking's radiation is gravity waves. 

"A research study using the James Webb Space Telescope has found that active galactic nuclei, supermassive black holes that grow rapidly, are less common than previously thought. This discovery suggests a more stable universe and provides insights into faint galaxies and challenges in identifying these nuclei." (ScitechDaily.com/What Happened to All the Supermassive Black Holes? Astronomers Surprised by Webb Data)

"While distant host galaxies for quasars and active galactic nuclei can often be imaged in visible/infrared light, the jets themselves and the surrounding emission is best viewed in both the X-ray and the radio, as illustrated here for the galaxy Hercules A. It takes a black hole to power an engine such as this, but that doesn’t necessarily mean that this is matter/radiation escaping from inside the event horizon." (BigThink.com/Ask Ethan: How does light escape from a black hole?)

We can say that the radiation jets from black holes have a connection with vaporization where black holes turn to radiation. The black holes help to create models that explain the gravitation. The result is that gravitation requires resistance or some kind of quantum field that presses particles or objects like a black hole into its form. Without that resistance or outside qauntum field black hole's vaporization turns so fast that it detonates. 

The fate of all black holes is vaporization. Those things turn into wave movement. And the reason for that is that no energy can replace the radiation that black holes send. Because black holes are losing mass, that means they send radiation. The wavelength of that radiation is gravity radiation or gravity waves. So black holes send radiation in the form of gravity waves. 

When black holes form in a supernova explosion. All material and energy will packed in the entirety called singularity. During a supernova explosion, the explosion blows all quantum fields out from the star. And then those quantum fields drop back to the place. Where stars have been.

Those falling quantum fields press all electrons, quantum fields, and quarks into an entirety that is smaller than atoms. Materia is one energy form and those quantum fields raise singularity's energy level so high that nothing can reach it. So black holes start to send gravitational radiation in the form of gravity waves around the universe. 

Two models can explain gravitational radiation and electromagnetic pikes at the black hole's poles. The idea in both models is that the singularity is so high-energy particle or object that nothing can cross the radiation wall around it. In some models, Hawking's radiation and the gravity waves that the black hole sends are the same thing. 

Whenever a singularity sends gravitational radiation it loses a little bit of its mass. Singularty's energy level is higher than any other particle, which means it can send radiation only in one direction. And that means nothing can replace that energy. This is the thing that causes the vaporization of black holes. 

Black holes are not black. They send radiation called gravity waves. So that means black holes are tensors that are turning all radiation that drops in that thing to gravitational radiation. There is the possibility that radiation that travels through the event horizon turns to gravitational radiation or gravity waves when they impact the singularity. In that model the energy reaches singularity but it cannot touch it and replace the lost energy that travels out from the black hole in the form of gravity waves. 

Model 1)

This model goes like this: When material and energy travel around the event horizon black hole pulls radiation in it. That radiation travels into the black hole and then reflects from the quantum gravity field around the singularity. The gravitational waves could fill the sphere behind the event horizon with radiation. And then sooner or later, that radiation goes too far from the singularity forming radiation that we see outside the black hole's event horizon. 

Black holes can pull radiation and material inside it. But that material and energy cannot reach the singularity in the middle of a black hole. In that version, the singularity sends gravitational radiation or gravity waves with so high frequency and short wavelength that nothing can reach the singularity itself. That means singularity can send radiation only in one direction. If no radiation or energy cannot replace that radiation the singularity will vaporize. 

Model 2 is almost the same as model 1)

Singularity is the point that spins at an extremely high speed. And if there is a so-called quantum channel in that extremely dense entirety, that channel can cause gravitational waves can travel to the black hole's poles. In that model, singularity aims all radiation through it and then conducts it to the black hole's poles. There could be a small quantum vacuum near those energy pikes and that energy rips the singularity in pieces or turns it to wave movement. 

https://bigthink.com/starts-with-a-bang/light-escape-black-hole/

https://scitechdaily.com/what-happened-to-all-the-supermassive-black-holes-astronomers-surprised-by-webb-data/

https://en.wikipedia.org/wiki/Fundamental_interaction