Chains from quantum gravitation models into neutron stars and black holes' models form the theory or idea of solid wave motion fields.
Can wave motion itself turn solid? The fact is that material and particles are a solid form of wave motion. But can wave motion or superstring form plate-shaped layers? And can that layer can act
But let's start with quantum gravitation.
Well, we can say that quantum gravitation is one version of gravitation. Every object with mass has a gravitational field, and that's it. Another name for gravitation should be a mass force. So if we think that every object with measurable mass has a gravitational field, we can say that lots of those objects with mass form stronger gravitational fields.
The reason why observing quantum gravitation is so difficult is that the object that is under research is so small. And its gravitational field is so weak.
Measuring the gravitational fields of single electrons and quarks is not an easy thing. But those objects can tell what is the thing, that causes gravitation? Is it radiation that travels through those particles?
Gravitational fields around extreme objects.
So lots of objects with quantum gravitational fields are forming planets, stars, neutron stars, and black holes. The last case is so different that we can only say that the quarks and electrons that formed the star before it turned into a black hole are somewhere behind an event horizon. But the form of those particles is different than it was before they turned into the black hole.
Sometimes people are talking about fermion stars. Well, all objects in the universe are formed of fermions. Fermions are forming atoms and all known material. Other elementary particle groups are bosons that transport some force.
Quark stars are the hypothetical medium between neutron stars and black holes massive gravitation pulls quantum fields off from the neutrons. That effect will uncover quarks that are forming those neutrons. In that case, the thing that is left is the ball of pure quarks.
The material should act like water in a gravitational field. When the gravitational field turns strong enough that forms ice. Gravitational ice is covering some extremely hot exoplanets. When pressure is low the water starts to boil at low temperatures.
If we put material in a bubble where are no quantum fields, that material turns wave motion. The reason for that is that the pressure of quantum fields cannot resist the incoming free energy. Or the particle just turns wave motion because energy travels out from it.
But if we continue this chain, we are facing a theoretical situation. Where an extremely powerful wave motion can turn solid in the powerful gravitational field. In another scenario, impacting wave motions can form a so-called solid wave motion field. That means the wave motion turns so strong that it can make a layer that seems solid. But that is pure theory.
But in black holes, the intensive gravitation makes something that we cannot even imagine. There is the possibility that wave motion can make solid layers that is acting like material. If we want to make the material by using some wave motion we must pull it to extreme pressure by using counter-wave motion.
Theoretically is possible to form a plate. That forms by pure wave motion or superstrings. There is the possibility that standing wave motion turns to solid form.
In that case, there must form skyrmions. And then both sides coming energy impacts are forming a layer that acts like material. That material could be the plate of superstrings. But there is one problem. Solid gravitational or electromagnetic field requires extremely high power energy.
https://scitechdaily.com/ask-a-caltech-expert-physicists-explain-quantum-gravity/
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