"An illustration (not to scale) of a primordial black hole growing to supermassive size. (Image credit: Robert Lea (created with Canva))" (Space.com, Tiny ‘primordial’ black holes created in the Big Bang may have rapidly grown to supermassive sizes)
If Kugelblitz- or black holes formed of radiation could be possible that explains how black holes could form before materia. In a very young universe, there was only radiation and energy. The thing that causes discussions is the question of which came first, black holes or regular material.
And did those primordial black holes form even before photons? Theoretically, it is possible to press a photon into a black hole by surrounding it with a thin energy string. If that energy string or energy lasso pumps enough energy to the photon it can turn into a small black hole. There is another possibility that allows that black hole to form straight from radiation.
That thing is that it’s possible that the radiation forms the energy pool. That large low-energy space can cause a situation where energy falls into the middle of it. That fallen energy impacts in the middle of that point. And there, the energy level rises so high, that there is a black hole. Theoretically, those Kugelblitz black holes are possible but they need lots of energy. And maybe those things could form in the young universe where the energy level was higher. But they cannot form in the modern universe, except in special situations where two black holes explode near each other. That can cause so high energy radiation that it can from the Kugelblitz.
In models, photons are wheel-shaped energy fields. There is a possibility that photons can form from “emptiness”. Or if two quantum fields impact each other they can form photons. And it's possible that some systems can press photons into the small, quantum-sized black hole. The photon itself is like some donut, so that causes the theorem that the graviton, the hypothetical gravitation transmitter particle, could be a quantum-size black hole that is in the middle of the photon. So if the graviton is in the middle of the photon, we can make an induction model, where dark matter could be gravitons or quantum black holes without that halo.
The cosmic vacuum can also form light. The idea is that the vacuum makes energy travel into that bubble. When that energy field impacts the vacuum’s wall, it turns those fields into light. So the light is the wave movement that forms in the impacts of those quantum fields. It’s like noise that forms when water flow impacts the water surface.
Primordial black holes could form straight from radiation that escaped from the Big Bang.
In this case, the event called Big Bang means the event or series of events that formed the universe as we know it. That even could be some kind of black hole explosion or something else that made energy move. When that event happened it sent radiation across the space. Then a little bit of that radiation or superstrings that formed the radiation turned around. That caused the superstring to turn around some other radiation packages. And that caused the energy level to rise at that point.
If photons existed in that time, the radiation string that surrounded the photon could start to pump energy into it. And that could form the first black hole. There was more radiation and the energy level in the young universe was far higher than in the modern universe. So if something formed the primordial black hole that thing will get more energy than black hole that exists in the modern universe. And that means even the primordial black holes could grow into enormous size faster than in the modern universe.
Researchers are really interested in things like Kugelblitz black holes. Those things can offer a new way to transport information. They can form the other side in the superpositioned and entangled particle pairs. But those may be microscopic black holes that offer new types of energy sources. They can also offer the possibility to see details of the subatomic particles by benefiting those black hole jets. The fact is that those black holes can be very stable if outside energy cannot let energy flow away from that point.
https://www.popularmechanics.com/science/a65046120/light-from-nothing/
https://scitechdaily.com/quantum-leap-scientists-reveal-the-shape-of-a-single-photon-for-the-first-time/
https://www.space.com/astronomy/black-holes/tiny-primordial-black-holes-created-in-the-big-bang-may-have-rapidly-grown-to-supermassive-sizes
https://en.wikipedia.org/wiki/Graviton
https://en.wikipedia.org/wiki/Kugelblitz_(astrophysics)
https://en.wikipedia.org/wiki/String_theory
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