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About the gravitational waves, strong nuclear force, and gluon interaction.





Image 1: Artists view of the neutron and its internal structure. Credit: Prof. Dr. Xiaorong Zhu, University for Science and Technology, China (ScitechDaily)


The quantum origin of the gravitational waves and gravitation might be in gluons. Or something that is between gluons.  So, could the gluon be the particle that is behind the gravitational waves?


When the energy level of gluons is rising. Those small subatomic particles are sending wave movement through the universe. Or actually, the energy flow away from gluons would begin just after the energy stress or energy pumping ends. 

The fact is that the gravitational wave doesn't require the graviton. The question is that the gravitational waves are the wave movement that origin is in the extremely small particles. When the extremely high mass objects impact together they are sending wave movement. 

So when the objects like neutron stars and black holes are impacting they are orbiting each other. And the energy is transferring between them. When the energy load of the objects is increasing it starts to anneal the gluons. And the gluons send the radiation or wave movement through the universe. 

The gravitational waves are the extremely weak wave movement in the universe. The fact is that every particle is sending gravitational waves. But only the most massive objects can send strong enough gravitational waves that researchers can see those wave movements with sensors. So the thing is that there must be some kind of particle or reaction that sends the gravitational wave moves through the universe. 

The idea is that the gravitational wave is the energy load that travels in the universe and changes the weight of the particles. So is the origin of the gravitational waves the interaction between some yet known material and antimatter particles. And could those particles maybe graviton and anti-graviton the hypothetical transportation particle of the gravitation. But that requires the existence of graviton.

 Or maybe, there is no need for antigraviton for sending the gravitational waves. The thing is that. If the source of the gravitational waves is small-size the wave movement that the particle sends. Affect only the quantum field around the atoms increasing the weight of the material. And then those quantum fields will resend the wave movement and particles to other quantum fields. The quantum field around the atom acts like gel. When a particle hits the quantum field shakes. And forming the small vacuum area and that pulls the other quantum fields to it. 


Are gluons the quantum origin of gravitation?


The gluons are particles that make quarks stay together in protons and neutrons. The structure of protons and neutrons is a little bit more complicated than the diagrams introduce. 

The idea is that maybe the quantum annealing of the extremely small subatomic particles causes the gravitational wave. The impact of extremely massive objects like neutron stars or black holes would cause that energy to be loaded into those extremely small particles that are sending that wave movement through the universe. 

But mainly, those particles are forming of three quarks and gluons that are traveling in them. The question is how the gluon will glue those quarks to one entirety? The answer for that thing might solve the question of which way the gravitation will affect. The idea is that when gluons are jumping between the quarks they are causing the "quantum vacuum" behind them. That vacuum will pull the quarks together. 

So that thing would explain why the strong nuclear force will interact only the short distance. And then the thing that makes the protons and neutrons stay together would be the "vacuum" of energy that follows the gluons. 

And then we must ask one very vital question. Is the energy vacuum the thing that forms the protons and neutrons? Can this energy vacuum form when the extremely small subatomic particles like gluon and anti gluon are impacting. That extremely small annihilation would push the quantum field away forming the quantum shockwave. Or actually, it could be acting like an extremely small nuclear detonator. 

That thing could form the quantum-size black hole that pulls the wave movements away from some area. And then the quarks are closing together. The gluons would be the debris of that wave movement. Or maybe the origin of gluons is in the quarks. When quarks impact, they are sent small sparks that are gluons together. 

In the case, that the protons and neutrons are hadron particles. Form around the electromagnetic or quantum energy vacuum. That thing means that the outside quantum force or quantum field pushes those particles together. The thing is that the quantum field is keeps the quarks together is the surface of protons and neutrons. 

When the particles hit together in the quantum world they are sending wave movement. That means they are acting like particles in our size world. When two quarks hit they are sending the wave movement like stones send soundwaves. The annihilation is the most high-energetic reaction in nature. 

That reaction happens between mirror particles. The only difference between antimatter and material particles is the polarity of those particles. So when the anti-particle hits with its mirror-particle that causes the quantum field around it will rip. And the subatomic particles are released. That means the subatomic particles in the protons and neutrons are sending the energy wave that looks like a flash of energy wave. 


https://www.ligo.caltech.edu/page/gravitational-waves


https://scitechdaily.com/new-insights-into-the-dynamic-inner-structure-of-the-neutron/


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


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


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


Image 1:https://scitechdaily.com/new-insights-into-the-dynamic-inner-structure-of-the-neutron/


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