There is a strange phenomenon where electrons vanish when they are cooled. The reason for that quantum phenomenon is that when electrons are cooling energy starts to travel in them. That energy falls in the middle of electrons. And then it reflects on their shell. The direction of energy flow depends on the energy level of the environment.
If an electron's energy level decreases very fast. That thing can turn it into wave movement because of that reflecting wave. When that wave reflects from an electron. That reflection makes around that electron a short-term electromagnetic vacuum. This quantum vacuum rips electrons into pieces if it exists long enough.
The ultra-short and high-power energy impulse can break electrons. When energy rises very fast in electrons and then it decreases very fast, that effect rips electrons into pieces. Or turn them into wave movement. That makes it possible to make a conclusion that ultra-powerful, short-term energy impulses can also turn all other elementary particles into wave movement.
"Artist's view of a quasiparticle composed of localized and mobile electrons, here broken up by an ultrashort light pulse. Credit: University of Bonn" (Phys.org)
If an electron's energy level is lower than the environment energy travels in it. And oppositely, if the electron's energy level is higher than its environment it sends energy or wave movement. When an electron receives energy and the energy level around it decreases all the time electron transmits energy out from it. All the time, when energy travels out from an electron it loses its mass. That thing causes an effect that turns electrons into wave movement.
All fundamental interactions are wave movements. And the size of interacting objects determines the distance of interaction. The reason why as an example weak nuclear force cannot interact in a long distance is that. The weak nuclear force is wave movement that an atom's nuclei send from the structure between the neutron's N/S poles.
The atom's nuclei send radiation from very thin areas or strings. Manly those strings or channels where Z and W bosons move are between the neutron's poles. And that radiation must travel through the electron shells. And that means it's quite hard to detect that radiation from long distances.
Why neutron star has a stronger gravitational field than Earth? The answer is that the neutron star's material is packed in an extremely dense form. Or we can say that the reason for that is that a neutron star is a homogenous object there is only one form of particles. Those particles are neutrons. Because in a neutron star is only neutrons. Those particles spin synchronously. Neutrons act like rolls. They transport quantum fields inside neutron stars.
That thing forms a gravitational pulling effect that moves objects inside the gravitational centers. The effect is similar to the electromagnetic pulling effect between magnetic N and S poles. All fundamental forces are interactions. And they all are similar forces. But the reason why gravitational force is weaker is that the interaction happens between much smaller particles than in electromagnetic interaction.
In a black hole, the spinning particles could be the gravitons. Those particles pull the quantum fields inside or through that object. And during that process, they send radiation that waves have the same wavelength or size as a particle that sends that radiation. So they just transform energy stored in material into another form.
So black holes and all other objects in the universe are not forming energy. They just turn one energy type or fundamental interaction into another form. All fundamental interactions are wave movement or one form of energy. And that means nuclear reactions are also not forming energy. They release energy that is stored in materials.
Can gravity remember? The fact is gravity is one wave movement form. Researchers try to create light-based optical USB sticks where information is stored in the laser ray, that travels between 100% reflecting mirrors. We can store information in laser rays. and that ability is used in everyday data transmissions. So why cannot we store information in gravitational waves? That thing requires an ability to interact and manipulate gravitational waves like researchers manipulate light and radiowaves in communication.
That means gravity should have the ability to store information. As well as all other wave movement frequencies can store information. So nothing denies the possibility that gravitational waves can someday act like laser rays and transport information through the universe. Because things like gamma rays and all other wave movement types can transport information gravitation should have the same ability.
And the ability to transport information means the ability to store information. Because without this ability, actors like particle or wave movement cannot transport information. If an actor "wants" to transport information it must store it first.
https://phys.org/news/2023-07-electrons-slowly-cooling-effect-unique.html
https://scitechdaily.com/unprecedented-precision-physicists-measure-the-wave-like-vibration-of-atomic-nuclei/
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