“Graphic showing the transverse motion of a quark (green sphere) inside a proton whose spin is aligned to its direction of motion (large yellow arrow). Credit: Image courtesy of Valerie Lentz/Brookhaven National Laboratory.” (ScitechDaily, How Do Quarks Really Move? New Theory Unlocks Decades-Old Physics Mystery)
Quarks are fermions. And gluons are bosons. That transports strong nuclear interaction. How do quarks really move? That thing can tell us about. The new things about the strong nuclear interaction. New models suggest that quarks have 3D movement tracks in a proton. And that causes an idea. The gluon, a boson that transmits the strong nuclear interaction, can simply spin between quarks. That spin forms a small “tornado” between quarks.
That tornado is the bond. That keeps those quarks. Under one entirety. Because that particle spins, it binds energy to it. And then that particle forms the quantum low-pressure between quarks. When gluon spin slows, that turns the pulling effect of the strong nuclear interaction weaker. If that gluon turns around or its spin direction turns opposite. That causes the effect. The gluon will send an energy impulse.
From it. In that moment, the quantum low pressure between quarks will be removed. And that pushes those particles away from each other. The quark’s 3D movement forms when some asymmetrical force impacts it. The knowledge of the quarks' behavior. increases the knowledge of the strong nuclear interaction. Because the spin speed of the gluon might not be stable. In the same way, the interaction between protons and electrons can change. And that causes an anomaly in the quark’s trajectory.
When a quark that may also spin collects energy from around it and from the quantum tornado. Or string it sometimes sends its extra energy away from it as some kind of particle. If the quark spins. It’s possible that the quark and gluon that connect two quarks spin into opposite directions to the tornado that connects those quarks into one entirety. There is a possibility that if a very low-energy free gluon impacts a particle, it removes energy from the gluon that connects quarks under one entity.
That slows the gluon speed. And maybe that thing can release the bond that keeps the quark in its position. Another devastating possibility can be that the extremely high-energy free gluons can send an energy impulse to the material around them. Those high-energy impulses can cause oscillation in gluons that keep protons and neutrons together. If that energy impulse suddenly stops, gluons between quarks send an energy impulse. And those impulses can fill those quantum low-pressure channels. That rips protons and neutrons into pieces.
https://scitechdaily.com/how-do-quarks-really-move-new-theory-unlocks-decades-old-physics-mystery/
https://en.wikipedia.org/wiki/Fundamental_interaction
https://en.wikipedia.org/wiki/Gluon
https://en.wikipedia.org/wiki/Neutron
https://en.wikipedia.org/wiki/Proton
https://en.wikipedia.org/wiki/Quark
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