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Can ultralight primordial black holes exist all around the universe?


"The simulated image shows how black holes bend a starry background and capture light, producing black hole silhouettes" (Interesting engineering, Ultralight, undying black holes could be all around the Universe)


The term: "ultralight black holes" consists of planetary mass black holes, atom, and quantum size black holes. The "Kugelblitz" black holes can be very light. "Kugelblitz"- black holes form straight from radiation. In certain situations, the FRB or some other energy burst that impacts the planet's atmosphere can press the planet so dense, that it turns into a black hole. 

Theoretically, also atoms and all other particles can turn into a black hole if they impact with an energy load that is high enough. In those cases, energy impulses press the atom's quantum fields symmetrically, and that energy pushes all particles in the atoms into one entirety. 

Can ultralight or quantum-size black holes be undying? The black hole is like a bubble in a gravity field. The interaction at the edge of a black hole is that the material disk pumps energy to the black hole. A black hole's gravity field is so powerful that it pulls wave movement inside it, and in the material disk, the electromagnetic radiation interacts with the material forming intensive heat. The question is, does the black hole pull gravity waves in it? 

The event horizon is a standing gravity wave or gravity field, and that should deny the gravitation itself falling in the black hole. Gravitation is an energy form or wave movement with a certain wavelength. The gravity field around black holes is a very powerful thing. Energy always travels into the lower energy space. 

That means the outcoming gravity waves cannot fall into the black hole. The reason for that is, the stronger gravity field pushes the outcoming gravity wave back. This means that the dense gravity field forms a situation in which all other wave movement falls in that bubble called a black hole, except gravitational waves.  

But gravitational waves can start to orbit a black hole. Those orbiting gravitational waves lock the gravitational field around the black hole. That gravitational ring also sends gravitational waves into the black hole. The material that orbits black holes is in a very high energy level. The kinetic energy of that material is massive. When material travels through quantum fields those fields increase the mass of that material. 

Sometimes a black hole pulls all material from its environment inside it. That separates the black hole from the material. And in that case, the energy field around it turns weaker. At that point, the black hole sends gravity waves.  So can the atom-size or smaller black hole be stable? 

Could the material and radiation called wave movement lock the gravitational field in that structure? The thing that denies the expansion of the black hole is the energy stability. The black hole can expand only if it gets more energy than it releases. In the form of gravity waves. It's possible. A small black hole forms the wave movement layer that locks the black hole in its form. 

If the energy level of that layer is high enough that forms a shell that doesn't allow energy and material to fall in the black hole. That wave movement shell can also lock gravity waves that the black hole sends inside it. This is one model that can turn very small and light black holes into stable ones. 


https://interestingengineering.com/space/ultralight-primordial-black-holes-universe

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