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Antimatter might have a bigger role in the material than we have thought.



Artistic rendering of quarks in deuterium. Credit: Ran Shneor (Image: I) 

The antimatter is the thing that is the most high-energetic in the world. When an antimatter particle impacts its mirror particle the result is an extremely high energetic annihilation. In an annihilation reaction, those particles turn to energy. Or if we are very accurate when the antimatter hits material it pulls the strings that are forming particles open. And the extremely high energetic radiation would start to travel through the space. 

So why the annihilation releases so much energy? Some people are saying that the energy impulse is releasing when the superstrings are open. Is like the slam of the whip but the size of the actors is smaller. The thing is that when the wave movement that formed the particles is moving ahead with extremely high speed. The head of the string can move faster than the ball-shaped photon. 

The reason for that is. The head of the wave movement is fitting between quantum fields easier than a ball-shaped photon.

The wave movement form of the light is the flat photon. So the speed of a flat photon is higher than the ball-shaped photon until it hits the quantum field and turns to particle form. 

But the thing is that annihilation is possible only between mirror-particles. So the anti-electron or positron would not annihilate with the proton. And one of the most interesting things in the world is that inside the proton are antimatter particles. Those particles are inside the quantum field of the proton. And there is an asymmetry in the antimatter quarks. The thing is that the antimatter quarks are between normal quarks.

But the anti-down quark between the up-quarks should not cause an annihilation reaction. When the proton is destroying or split one of the reasons for that is that the quantum fields around them are turning too big. The gluons cannot keep those mirror particles separated. So the antiquarks will touch each other and then the internal annihilation destroys the proton. The thing that makes quantum annihilation interesting.  

Adjustment of the quark annihilation is more accurate than annihilation between higher particles. That thing means that quark-antiquark annihilation can use the energy supply for nanomachines. Or that reaction can destroy cancer cells from the body. 


https://www.britannica.com/science/annihilation

https://phys.org/news/2021-10-quarks-antiquarks-high-momentum-foundations.html?fbclid=IwAR3t304m-q5xFD0KKqYys9DufSIEBlvt-2K480ij3GY1Mb5bmMuKv-PcEgk

(Image I) https://phys.org/news/2021-10-quarks-antiquarks-high-momentum-foundations.html?fbclid=IwAR3t304m-q5xFD0KKqYys9DufSIEBlvt-2K480ij3GY1Mb5bmMuKv-PcEgk


https://thoughtandmachines.blogspot.com/


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